High-rate at high-density tunable accumulation conveyor

ABSTRACT

Various embodiments disclosed herein provide for an improved accumulation conveyor and systems and methods for controlling a high rate, high density tunable accumulation conveyor. In one embodiment, an accumulation conveyor system determines whether an item detection variable associated with a second zone of a plurality of zones is satisfied, wherein the second zone is downstream of a first zone. The accumulation conveyor system determines whether at least one of two operational characteristic variables is satisfied. In an instance where both the item detection variable and at least one operational characteristic variable are satisfied, the accumulation conveyor system is configured to set a zone operating state associated with the first zone to inactive and send a command signal comprising the zone operating state associated with the first zone to a control module associated with the first zone. In another embodiment, an improved method for adjusting aggressiveness is disclosed. In another embodiment, a tunable release rate accumulation conveyor is disclosed. In still another embodiment, a tunable crowding accumulation conveyor is disclosed.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional PatentApplication No. 62/799,489, filed Jan. 31, 2019, the entire contents ofwhich are incorporated by reference herein.

TECHNICAL FIELD

The present application relates generally to the field of accumulatingconveyors and, more specifically, to enhanced control systems forincreasing density and throughput and tuning of accumulation conveyors.

BACKGROUND

Various accumulation conveyors are available that convey, transport,organize and accumulate products, articles, and/or the like in materialor product handling environments. Accumulation conveyors are broken intomany separately controlled zones and as product is detected in each zonewith sensors (such as photoeyes), the zones fill up, and these zones areshut off or disabled, stopping and accumulating the product into groups.As zones empty out, the accumulation conveyor enables (e.g., energizes)other zones in order to cause the product to go. The way an accumulationconveyor (or accumulating conveyor) handles both the going and thestopping is referred to as the “accumulation logic”. Applicant hasidentified a number of deficiencies and problems associated withconventional accumulation conveyors and existing accumulation logic,methods, and systems for controlling the operation of such accumulationconveyors. Through applied effort, ingenuity, and innovation, many ofthese identified problems have been solved by developing solutions thatare included in embodiments of the present disclosure, many examples ofwhich are described in detail herein

BRIEF SUMMARY

Various embodiments provided herein disclose improved systems,accumulation conveyors, and methods for controlling and tuning anaccumulation conveyor to increase the density and throughput of suchaccumulation conveyor.

One embodiment is directed to an accumulation conveyor system comprisinga conveyor having a plurality of zones; one or more sensors associatedwith each zone of the plurality of zones; one or more control modulesassociated with the plurality of zones; a controller in communicationwith the one or more control modules, the controller comprising at leastone processor and at least one memory, the at least one memory storingexecutable instructions therein, wherein the executable instructions areconfigured to, in execution with the at least one processor, cause thecontroller to: determine whether an item detection variable associatedwith a second zone of the plurality of zones is satisfied, wherein thesecond zone is downstream of a first zone; determine whether at leastone of two operational characteristic variables is satisfied, the twooperational characteristic variables comprising a first operationalcharacteristic variable and a second operational characteristicvariable; in an instance where both the item detection variable and atleast one operational characteristic variable are satisfied, set a zoneoperating state associated with the first zone to inactive; and send acommand signal comprising the zone operating state associated with thefirst zone to the control module associated with the first zone.

In one embodiment, in an instance where the item detection variable isnot satisfied, the executable instructions are further configured tocause the controller to set the zone operating state associated with thefirst zone to active.

In some embodiments, the item detection variable associated with thesecond zone is satisfied when a presence of an object on the conveyor isdetected via the one or more sensors associated with the second zone. Incertain embodiments, at least one of the one or more sensors associatedwith the second zone is a photo eye. In still further embodiments, theitem detection variable associated with the second zone is satisfiedwhen the controller receives a blocked signal from the photo eye.

In some embodiments, in an instance where the first operationalcharacteristic variable and the second operational characteristicvariable are not satisfied, the executable instructions are furtherconfigured to cause the controller to set the zone operating stateassociated with the first zone to active.

In some embodiments, the first operational characteristic variable issatisfied when a zone operating state associated with the second zone isinactive.

In some embodiments, the first zone is associated with a rollercountdown timer and the second operational characteristic variable issatisfied when the roller countdown timer is expired. In certainembodiments, the roller countdown timer is configured to activate eachinstance the zone operating state associated with the first zone isinactive. In still further embodiments, the roller countdown timer isconfigured to reset each instance the zone operating state associatedwith the first zone is active.

In some embodiments, the first zone is assigned a local zone number andthe second operational characteristic variable is satisfied when thelocal zone number is less than a threshold associated with assignment oflocal zone numbers.

Still other embodiments are directed to a method of controlling arelease rate of one or more zones of an accumulation conveyor, themethod comprising detecting an indication to adjust a first release rateassociated with a first zone, wherein the first release rate isseparately configurable from a level of accumulation aggressiveness ofthe accumulation conveyor; determining a second release rate associatedwith the first zone based upon at least a configured speed of the firstzone and generating a release rate timer corresponding to the secondrelease rate; activating the release rate timer associated with thefirst zone; and upon expiration of the release rate timer associatedwith the first zone, activating a second zone, wherein the second zoneis upstream of the first zone.

In one embodiment, detecting an indication to adjust the first releaserate associated with the first zone is based upon user input receivedvia a controller user interface. In some embodiments, the configuredspeed of the first zone is determined based upon a percentage of amaximum speed associated with the first zone and the detected indicationto adjust the first release rate.

In still further embodiments, the method further comprises detecting anindication to adjust a third release rate associated with a third zone;determining a fourth release rate associated with the third zone basedupon at least a configured speed of the third zone and generating arelease rate timer corresponding to the fourth release rate, wherein thefourth release rate associated with the third zone is different than thesecond release rate associated with the first zone; activating therelease rate timer associated with the third zone; and upon expirationof the release rate timer associated with the third zone, activating afourth zone, wherein the fourth zone is upstream of the third zone.

Still other embodiments are directed to a method of adjusting a level ofaccumulation aggressiveness associated with an accumulation conveyorcomprising receiving conveyor data input, the conveyor data inputcomprising configuration variables associated with the accumulationconveyor; querying an accumulation settings repository for accumulationsettings based upon at least the conveyor data input; determining aninitial accumulation mode based upon at least the conveyor data inputand the accumulation settings returned by the query, the initialaccumulation mode associated with one or more aggressiveness parameters;programmatically generating an aggressiveness linear equation based uponat least the accumulation settings returned by the query; assigning anaggressiveness value associated with the initial accumulation mode as adefault value of the aggressiveness linear equation; and in response todetecting a change in the aggressiveness value, adjusting at least oneof the one or more aggressiveness parameters associated with the initialaccumulation mode in accordance with the aggressiveness linear equation.

In some embodiments, adjusting at least one of the one or moreaggressiveness parameters associated with the initial accumulation modein accordance with the aggressiveness linear equation adjusts the levelof accumulation aggressiveness associated with the accumulation conveyorin comparison to the default value.

In certain embodiments, detecting a change in the aggressiveness valuecorresponds to an indication of increasing the aggressiveness value. Insome embodiments, detecting a change in the aggressiveness valuecorresponds to an indication of decreasing the aggressiveness value.

In some embodiments, the method further comprises rendering anaggressiveness configuration interface to a controller user interface,wherein the conveyor data input is associated with user engagement ofthe aggressiveness configuration interface; and configuring anaggressiveness interface object based upon at least the aggressivenesslinear equation and the default value and outputting the aggressivenessinterface object to the controller user interface, wherein detecting achange in the aggressiveness value comprises receiving user inputassociated with user engagement of the aggressiveness interface object.

The details of one or more embodiments of the subject matter describedin this specification are set forth in the accompanying drawings and thedescription below. Other features, aspects, and advantages of thesubject matter will become apparent from the description, the drawings,and the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

Non-limiting and non-exhaustive embodiments of the subject disclosureare described with reference to the following figures, wherein likereference numerals refer to like parts throughout the various viewsunless otherwise specified.

FIG. 1 illustrates an example zone-based accumulation conveyor inaccordance with various aspects and embodiments of the subjectdisclosure;

FIG. 2 illustrates a schematic view of a controller in accordance withvarious aspects and embodiments of the subject disclosure;

FIG. 3 illustrates a flow diagram of logic for determining the operatingstate of an individual zone in accordance with various aspects andembodiments of the subject disclosure;

FIG. 4A is a flowchart illustrating example operations for controllingaccumulation in accordance with various aspects and embodiments of thesubject disclosure;

FIG. 4B is a flowchart illustrating example operations for controllingrelease rate in accordance with various aspects and embodiments of thesubject disclosure

FIG. 5 illustrates an example aggressiveness interface object inaccordance with various aspects and embodiments of the subjectdisclosure; and

FIG. 6 illustrates an example release rate interface object inaccordance with various aspects and embodiments of the subjectdisclosure.

DETAILED DESCRIPTION Overview

Accumulation conveyors (or accumulating conveyors) are commonly used inproduct handling environments for the transport, grouping, accumulation,and collecting together of materials, products, or articles.Accumulation of articles into groups, often called slugs, reduces delaysin material handling by temporarily stopping or holding, articles andthen releasing such articles in coordination with other downstreamoperations. As the product density increases on the conveyor, however,the rate of flow of said product diminishes significantly therebycausing the whole conveyor system to slow down, backing up and shuttingdown upstream feeding conveyors, even in situations where everything ismoving. Existing accumulation modes (logic and/or circuit) are built ona traditional model based on historic mechanical conveyor controls wherespring-powered pop-up rollers would mechanically turn on and off otherrollers. These modes do not differentiate from when product isaccumulating vs. flowing, causing the rate of flow to diminish at higherdensities. For example, in the simplest case, even when product isflowing through a zone, because it is blocking the sensor, the upstreamzone is slowing down because it thinks it should be accumulating.

Typically, in an effort to increase the rate of flow, there are controlstrategies used today such as ‘slugging’ (e.g., turning on all zones)that would make all product move at its highest rate if the wholeconveyor is flowing. However, because of the purpose and usual length ofthe conveyors in the hundreds of feet, usually there are multiple thingsor processes occurring at multiple areas of the same conveyor. Forexample, various parts of the conveyor may be releasing, accumulating,staying still, or re-indexing forward, while others may be flowing. Assuch, slugging all of these conveyor areas essentially defeats thepurpose of an accumulating conveyor. Thus, it is desirable for anaccumulation conveyor to support both a high product density and highrate of flow while maintaining its ability to provide accumulation ofproduct.

Other efforts to increase the rate of flow and/or adjust theaggressiveness of accumulation by adjusting or stacking operationalmodes in existing accumulation control systems has proven to becomplicated and non-intuitive. That is, an existing control system canallow many different accumulation configurations and operational modesto be applied, but the downside of having a variety of accumulationconfiguration parameters is the plethora of additional operational modeswhich can be stacked together, sometimes helping but usually hurtingproduct handling and rate depending on their combination Tuning thesesettings on an accumulating conveyor have proven challenging andrequiring a very specific expertise that most field engineers lack dueto the infrequency of contact and them being stretched across so manydifferent products in a conveyor system. As such, setting up andadjusting current accumulation conveyor systems by stacking operationalmodes without guidance is prone to error, resulting in missed deadlinesand product damage. Thus, it is also desirable to provide anaccumulation conveyor system that is more intuitive and allows for easyset-up and adjustments with little downtime.

Various embodiments disclosed herein provide for an accumulationconveyor that enables high rate, high density accumulation. That is,various embodiments of the present invention are directed to improvedsystems, accumulation conveyors, and methods for controlling anaccumulation conveyor to increase the density and throughput of suchaccumulation conveyor. In one example, one or more sensors areassociated with each zone of an accumulation conveyor, the accumulationconveyor comprising a plurality of zones. Such sensors are configured tomonitor the occupancy of a zone by a product or item transporting on theconveyor. In combination with one or more other data items, such as theoperating state of a downstream zone, the status of local zone rollertimer, the status of a prejam timer, the status of a release rate time,such sensor data and status data may then be utilized to configure theoperating state of a local zone to improve accumulation. In someembodiments, the accumulation aggressiveness and/or release rate areeach configured to be adjustable via sliding linear scales, affordingcost and time savings as well as simplifying the setup and fine-tuningof accumulation conveyor systems. Accordingly, the present disclosureprovides example technological improvement that result in improvedsystems, accumulation conveyors, and methods for controlling anaccumulation conveyor to increase, in some examples, the density andthroughput of such accumulation conveyor.

Definitions

One or more embodiments are now more fully described with reference tothe drawings, wherein like reference numerals are used to refer to likeelements throughout. In the following description, for purposes ofexplanation, numerous specific details are set forth in order to providea thorough understanding of the various embodiments. It is evident,however, that the various embodiments can be practiced without thesespecific details (and without applying to any particular networkedenvironment or standard). It should be understood that some, but not allembodiments are shown and described herein. Indeed, the embodiments maybe embodied in many different forms, and accordingly this disclosureshould not be construed as limited to the embodiments set forth herein.Rather, these embodiments are provided so that this disclosure willsatisfy applicable legal requirements.

The terms “accumulation conveyor” and “accumulating conveyor” refer toany conveyor, carousel, assembly line, production line, conveyor belt,and/or any other form of object utilized for moving, transporting, andaccumulating product, components, materials, articles, or items and issuitable for use or operation in a product handling environment.

As used herein, an individual zone being examined at a given time may bereferred to when being examined as the “local zone.” The “downstreamdirection” or “downstream” is the direction articles travel on anaccumulation conveyor, and “upstream direction” or “upstream” is thedirection opposite of the direction articles travel on an accumulationconveyor. A “downstream zone” is a zone which is disposed in thedownstream direction from another zone. An “upstream zone” is a zonewhich is disposed in the upstream direction from another zone. By way ofillustration and not limitation, referring to FIG. 1, in an instancewherein zone 4 b is the local zone, zone 4 a is an upstream zone andzone 6 a is a downstream zone. Herein for convenience, these upstreamand downstream zones are referred to as a “neighborhood.” An upstreamneighborhood and a downstream neighborhood may extend one or more zonesin the particular direction. The operational mode effected by a controlscheme that considers the conditions of one or more neighboring zones sreferred to as a “neighborhood mode.” Neighborhood is used herein onlyas a label referring to this type of control scheme, and does notrepresent a limitation on the scope of the claims.

The term “comprising” means including but not limited to and should beinterpreted in the manner it is typically used in the patent context.Use of broader terms such as comprises, includes, and having should beunderstood to provide support for narrower terms such as consisting of,consisting essentially of, and comprised substantially of. Furthermore,to the extent that the terms “includes” and “including” and variantsthereof are used in either the detailed description or the claims, theseterms are intended to be inclusive in a manner similar to the term“comprising.”

The phrases “in one embodiment,” “according to one embodiment,” and thelike generally mean that the particular feature, structure, orcharacteristic following the phrase may be included in the at least oneembodiment of the present invention and may be included in more than oneembodiment of the present invention (importantly, such phrases do notnecessarily refer to the same embodiment).

Moreover, the word “exemplary” is used herein to mean “serving as anexample, instance, or illustration.” Any implementation, aspect, ordesign described herein as “exemplary” is not necessarily to beconstrued as preferred or advantageous over other implementations,aspects, or designs. Rather, use of the word exemplary is intended topresent concepts in a concrete fashion.

As used in this application, the term “or” is intended to mean aninclusive “or” rather than an exclusive “or”. That is, unless specifiedotherwise, or clear from context, “X employs A or B” is intended to meanany of the natural inclusive permutations. That is, if X employs A; Xemploys B; or X employs both A and B, then “X employs A or B” issatisfied under any of the foregoing instances. In addition, articles“a” and “an” as used in this application and the appended claims shouldgenerally be construed to mean “one or more” unless specified otherwiseor clear from context to be directed to a singular form.

The terms “about” or “approximately” or the like, when used with anumber, may mean that specific number, or alternatively, a range inproximity to the specific number, as understood by persons of skill inthe art field.

If the specification states a component or feature “may,” “can,”“could,” “should,” “would,” “preferably,” “possibly,” “typically,”“optionally,” “for example,” “often,” or “might” (or other suchlanguage) be included or have a characteristic, that particularcomponent or feature is not required to be included or to have thecharacteristic. Such component or feature may be optionally included insome embodiments, or it may be excluded.

The term “aggressiveness of accumulation” is used herein to refer to anamount of intensity of impact as product accumulates or how hard or softproduct hits other product as such product slows down on the conveyor.

The term “item detection variable” should be understood to refer to oneor more variables, parameters, criteria, or conditions associated withthe detection of an item which is used to determine the zone operatingstate for one or more zones. In some embodiments, the item detectionvariable defines the variables, parameters, criteria, or conditions todetermine whether an item is detected in a particular zone. Zone sensordata is utilized to determine whether a sensor associated with aselected zone indicates an item is detected such that the selected zonemay be occupied. In some embodiments, if a sensor associated with aselected zone transmits a signal indicating detection of an item (e.g.,a blocked signal from a photo eye) for a period of time equal to orgreater than a pre-determined time period, such as e.g., zero, 0.75seconds, 1.0 seconds or 1.5 seconds, such zone is considered occupied.In some embodiments, an item detection variable is satisfied with aselected zone when the zone sensor data associated with the selectedzone indicates such zone is occupied. For example, an item detectionvariable associated with a downstream zone is satisfied when a presenceof an item on the conveyor is detected via the one or more sensorsassociated with the downstream zone. An item detection variableassociated with a downstream zone is not satisfied when a presence of anitem on the conveyor is not detected via the one or more sensorsassociated with the downstream zone. Such item detection variable may beused to determine the zone operating state for a different selectedzone.

The term “operational characteristic variable” should be understood torefer to one or more variables, parameters, criteria, or conditionsassociated with operational characteristics of one or more zones whichis used to determine the zone operating state for one or more zones. Insome embodiments, the operational characteristic variable defines thevariables, parameters, criteria, or conditions to determine whether anitem is detected in a particular zone. Operational characteristics mayinclude the zone operating state of a zone, a comparison of a local zonenumber to some value X, be associated with a roller countdown timer of azone, and/or the like. In some embodiments, the determination that oneor more operational characteristic variables are satisfied may be usedto determine the zone operating state for one or more zones. Forexample, in some embodiments, an operational characteristic variable issatisfied if the zone operating state of a selected zone is OFF. Instill further embodiments, an operational variable is not satisfied ifthe zone operating state of a selected zone is ON. In certainembodiments, an operational characteristic variable may be satisfied ifa roller countdown timer associated with a zone is expired and anoperational characteristic variable may not be satisfied if a rollercountdown timer associated with a zone is not expired. In still furtherembodiments, an operational characteristic variable may be satisfied ifa local zone number is less than or equal to some value and may not besatisfied if the local zone number is greater than such value. Theoperational characteristic variables may be associated with a firstzone, a second zone, or any number of zones and need not be associatedwith the same zone.

As used herein, the terms “data,” “content,” “digital content,” “digitalcontent object,” “information,” and similar terms may be usedinterchangeably to refer to data capable of being captured, transmitted,received, and/or stored in accordance with various embodiments of thepresent invention. Thus, use of any such terms should not be taken tolimit the spirit and scope of embodiments of the disclosure. Further,where a computing device is described herein to receive data fromanother computing device, it will be appreciated that the data may bereceived directly from another computing device or may be receivedindirectly via one or more intermediary computing devices, such as, forexample, one or more servers, relays, routers, network access points,base stations, hosts, repeaters, and/or the like, sometimes referred toherein as a “network.” Similarly, where a computing device is describedherein to send data to another computing device, it will be appreciatedthat the data may be transmitted directly to another computing device ormay be transmitted indirectly via one or more intermediary computingdevices, such as, for example, one or more servers, relays, routers,network access points, base stations, hosts, repeaters, and/or the like.

As used in this application, the terms “system,” “component,”“interface,” and the like are generally intended to refer to acomputer-related entity or an entity related to an operational machinewith one or more specific functionalities. The entities disclosed hereincan be either hardware, a combination of hardware and software,software, or software in execution. For example, a component may be, butis not limited to being, a process running on a processor, a processor,an object, an executable, a thread of execution, a program, and/or acomputer. By way of illustration, both an application running on aserver and the server can be a component. One or more components mayreside within a process and/or thread of execution and a component maybe localized on one computer and/or distributed between two or morecomputers. These components also can execute from various computerreadable storage media having various data structures stored thereon.The component may communicate via local and/or remote processes such asin accordance with a signal having one or more data packets (e.g., datafrom one component interacting with another component in a local system,distributed system, and/or across a network such as the Internet withother systems via the signal). As another example, a component can be anapparatus with specific functionality provided by mechanical partsoperated by electric or electronic circuitry that is operated assoftware or firmware application(s) executed by a processor, wherein theprocessor can be internal or external to the apparatus and executes atleast a part of the software or firmware application. As yet anotherexample, a component can be an apparatus that provides specificfunctionality through electronic components without mechanical parts,the electronic components can comprise a processor therein to executesoftware or firmware that confers at least in part the functionality ofthe electronic components. An interface can comprise input/output (I/O)components as well as associated processor, application, and/or APIcomponents.

As it employed in the subject specification, the term “processor” canrefer to substantially any computing processing unit or devicecomprising, but not limited to comprising, single-core processors;single-processors with software multithread execution capability;multi-core processors; multi-core processors with software multithreadexecution capability; multi-core processors with hardware multithreadtechnology; parallel platforms; and parallel platforms with distributedshared memory. Additionally, a processor can refer to an integratedcircuit, an application specific integrated circuit (ASIC), a digitalsignal processor (DSP), a field programmable gate array (FPGA), aprogrammable logic controller (PLC), a complex programmable logic device(CPLD), a discrete gate or transistor logic, discrete hardwarecomponents, or any combination thereof designed to perform the functionsdescribed herein. Processors can exploit nano-scale architectures suchas, but not limited to, molecular and quantum-dot based transistors,switches and gates, in order to optimize space usage or enhanceperformance of user equipment. A processor also can be implemented as acombination of computing processing units.

Further, terms like “user equipment,” “user device,” “mobile device,”“mobile,” “station,” “access terminal,” “terminal,” “handset,” andsimilar technology, generally refer to a wireless device utilized by asubscriber or user of a wireless communication network or service toreceive or convey data, control, voice, video, sound, gaming, orsubstantially any data-stream or signaling-stream. The foregoing termsare utilized interchangeably in the subject specification and relateddrawings. Likewise, the terms “access point,” “node B,” “base station,”“evolved Node B,” “cell,” “cell site,” and the like, can be utilizedinterchangeably in the subject application, and refer to a wirelessnetwork component or appliance that serves and receives data, control,voice, video, sound, gaming, or substantially any data-stream orsignaling-stream from a set of subscriber stations. Data and signalingstreams can be packetized or frame-based flows. It is noted that in thesubject specification and drawings, context or explicit distinctionprovides differentiation with respect to access points or base stationsthat serve and receive data from a mobile device in an outdoorenvironment, and access points or base stations that operate in aconfined, primarily indoor environment overlaid in an outdoor coveragearea. Data and signaling streams can be packetized or frame-based flows.

Furthermore, the terms “user,” “subscriber,” “customer,” “consumer,” andthe like are employed interchangeably throughout the subjectspecification, unless context warrants particular distinction(s) amongthe terms. It should be appreciated that such terms can refer to humanentities, associated devices, or automated components supported throughartificial intelligence (e.g., a capacity to make inference based oncomplex mathematical formalisms) which can provide simulated vision,sound recognition and so forth. In addition, the terms “wirelessnetwork” and “network” are used interchangeable in the subjectapplication, when context wherein the term is utilized warrantsdistinction for clarity purposes such distinction is made explicit.

In the subject specification, terms such as “store,” “data store,” “datastorage,” “database,” “repository,” “queue”, and substantially any otherinformation storage component relevant to operation and functionality ofa component, refer to “memory components,” or entities embodied in a“memory” or components comprising the memory. It will be appreciatedthat the memory components described herein can be either volatilememory or nonvolatile memory, or can comprise both volatile andnonvolatile memory. In addition, memory components or memory elementscan be removable or stationary. Moreover, memory can be internal orexternal to a device or component, or removable or stationary. Memorycan comprise various types of media that are readable by a computer,such as hard-disc drives, zip drives, magnetic cassettes, flash memorycards or other types of memory cards, cartridges, or the like.

By way of illustration, and not limitation, nonvolatile memory cancomprise read only memory (ROM), programmable ROM (PROM), electricallyprogrammable ROM (EPROM), electrically erasable ROM (EEPROM), or flashmemory. Volatile memory can comprise random access memory (RAM), whichacts as external cache memory. By way of illustration and notlimitation, RAM is available in many forms such as synchronous RAM(SRAM), dynamic RAM (DRAM), synchronous DRAM (SDRAM), double data rateSDRAM (DDR SDRAM), enhanced SDRAM (ESDRAM), Synchlink DRAM (SLDRAM), anddirect Rambus RAM (DRAM). Additionally, the disclosed memory componentsof systems or methods herein are intended to comprise, without beinglimited to comprising, these and any other suitable types of memory.

In particular and in regard to the various functions performed by theabove described components, devices, circuits, systems and the like, theterms (including a reference to a “means”) used to describe suchcomponent are intended to correspond, unless otherwise indicated, to anycomponent which performs the specified function of the describedcomponent (e.g., a functional equivalent), even though not structurallyequivalent to the disclosed structure, which performs the function inthe herein illustrated example aspect of the embodiments. In thisregard, it will also be recognized that the embodiments comprises asystem as well as a computer-readable medium having computer-executableinstruction for performing the acts and/or events of the variousmethods.

Computing devices typically comprise a variety of media, which cancomprise “computer-readable storage media” and/or “communicationsmedia,” which two terms are used herein differently from one another asfollows. “Computer-readable storage media” can be any available storagemedia that can be accessed by the computer and comprises both volatileand nonvolatile media, removable and non-removable media. By way ofexample, and not limitation, computer-readable storage media can beimplemented in connection with any method or technology for storage ofinformation such as computer-readable instructions, program modules,structured data, or unstructured data. Computer-readable storage mediacan comprise, but are not limited to, RAM, ROM, EEPROM, flash memory orother memory technology, CD-ROM, digital versatile disk (DVD) or otheroptical disk storage, magnetic cassettes, magnetic tapes, magnetic diskstorage or other magnetic storage devices, or other tangible and/ornon-transitory media which can be accessed by one or more local orremote computing devices, e.g., via access requests, queries or otherdata retrieval protocols, for a variety of operations with respect tothe information stored by the medium.

On the other hand, “communications media” typically embodycomputer-readable instructions, data structure, program modules or otherstructure or unstructured data in a data signal such as a modulated datasignal, e.g., a carrier wave or other transport mechanism, and comprisesany information delivery or transport media. The term “modulated datasignal” or signals refers to a signal that has one or more of itscharacteristics set or changed in such a manner as to encode informationin one or more signals. By way of example, and not limitation,communications media comprise wired media, such as a wired network ordirect-wired connection, and wireless media such as acoustic, RF,infrared and other wireless media.

System Architecture and Example Apparatus for Implementing Embodimentsof the Present Disclosure

Methods, apparatuses, systems, and computer program products of thepresent invention may be embodied by any of a variety of devices. Forexample, the method, apparatus, system, and computer program product ofan example embodiment may be embodied by a networked device, such as aserver or other network entity, configured to communicate with one ormore devices, such as the one or more sensors or the one or more zonecontrol modules associated with an accumulation conveyor. Additionally,or alternatively, the computing device or controller may include fixedcomputing devices, such as a personal computer or a computerworkstation. Still further, example embodiments may be embodied by anyof a variety of mobile terminals, such as a portable digital assistant(PDA), mobile telephone, smartphone, laptop computer, tablet computer,or any combination of the aforementioned devices. Still further, exampleembodiments may be embodied by devices utilizing IoT (Internet ofThings) or IIoT (Industrial Internet of Things) technology. In stillfurther embodiments, the method, apparatus, system, and computer programproduct of an example embodiment may be embodied in, have access to, orotherwise be associated with a gateway device or cloud-based platform.

Referring to FIG. 1, there is shown a diagrammatic plan view of anaccumulation conveyor embodying one or more teachings of the presentdisclosure. Accumulation conveyor, generally indicated at 2, includes aplurality of zones 4 a, 4 b, 6 a, 6 b, 8 a, 8 b, 10 a, 10 b and 12 a,which are individually controllable. Although in the embodiment depictedin FIG. 1 there are nine zones, the present invention is not limited tonine zones, or an odd or even number of zones. In the embodimentdepicted, zones are generally three feet long, although they may be ofany suitable length, such as six feet. In the embodiment depicted, zonecontrol modules 4 c, 6 c, 8 c and 10 c each controls two zones, althougha zone control module may control more than two zones or control onlyone zone, which discharges to conveyor 14. The number of zones that asingle zone control module may control is not limited to the presentinvention.

In the embodiment depicted, each zone of accumulation conveyor 2comprises one or more conveyor rollers (diagrammatically illustrated)defining a conveyor surface, which may be selectively driven such as byan underlying chain or a drive belt (not shown) urged against theconveyor rollers using one or more pneumatic actuators (not shown). Inthe depicted embodiment, each control module 4 c, 6 c, 8 c, 10 c and 12c is configured to control the one or more pneumatic actuators (notshown) of their associated zones, and is therefore connected to apneumatic source. In some embodiments, the control modules 4 c, 6 c, 8c, 10 c and 12 c may be pneumatically daisy chained together. Otherdrive roller, and/or belt configurations or arrangements are alsocontemplated by this disclosure, including but not limited to, motorizeddriven rollers with control modules 4 c, 6 c, 8 c, 10 c and 12 cconfigured appropriately therefor, or one or more control modules 4 c, 6c, 8 c, 10 c and 12 c encompassed within or associated directly with aroller, such that one or more rollers are further configured perform thefunctionality of a control module.

Each zone 4 a, 4 b, 6 a, 6 b, 8 a, 8 b, 10 a, 10 b and 12 a includesrespective sensors 4 d, 4 e, 6 d, 6 e, 8 d, 8 e, 10 d, 10 e and 12 dthat are connected to the respective control modules of the zones. Inthe embodiment depicted, the sensors are photo eyes with respectivereflectors, although any suitable sensor may be used, such as rollersensors or diffused scan sensors. The positions and orientations of thesensors, also referred to herein as photo eyes, within the zones areselected based on the system parameters, such as length or type ofpackages. Although FIG. 1 is a diagrammatic illustration, sensors 4 d, 4e, 6 d, 6 e, 8 d, 8 e, 10 d, 10 e and 12 d are depicted as proximal thedischarge end of each zone, such as about one foot from the discharge.Any suitable location may be used, such as proximal the feed end of eachzone.

In the embodiment depicted, control modules 4 c, 6 c, 8 c, 10 c and 12 care networked together with controller 16, communicating data tocontroller 16 indicative of conditions of the plurality of zones 4 a, 4b, 6 a, 6 b, 8 a, 8 b, 10 a, 10 b and 12 a. Although a daisy chainconfiguration is depicted, any suitable network may be used. Similarlyalthough controller 16 is depicted as being a single physical device, acontroller in an embodiment of the disclosed technology could beimplemented in other ways as well, such as in the form of multipleintegrated physical devices, or multiple discrete physical devices whichcommunication with each other and/or other devices via a network (e.g.,a daisy chain network). That is, although a centralized controller isdepicted in FIG. 1, this disclosure contemplates other configurations,such as multiple integrated or discrete physical devices which allow fore.g. a distributed plug-n-play type environment, wherein each separatecontroller or physical device executes similar control logic, such asaccumulation logic or release rate logic, to control one or moreaccumulation conveyors 2.

Controller 16, which comprises at least one processor, comprises atleast part of a processing system, which itself may have more than onecontroller, which executes processor-executable instructions to performoperations to control accumulation conveyor 2. In the embodimentdepicted, logic for control of accumulation conveyor 2 is resident oncontroller 16, which executes instructions that implement the controllogic. Each zone 4 a, 4 b, 6 a, 6 b, 8 a, 8 b, 10 a, 10 b and 12 a has arespective settable operating speed that may be set by controller 16.Controller 16 may control more than one accumulation conveyor line. Insome embodiments depicted, controller 16 executes instructions toimplement the control logic of an embodiment of the present disclosure.

Aspects of the technology described herein can provide improvedoperating mode determination, thereby allowing the accumulation conveyor2 to operate at a higher speed with a higher article density whileproviding gentle handling of articles at the higher speed. In existing,traditional modes, the local zone uses the status of the firstdownstream zone sensor to determine its own operating state. Forexample, in a traditional mode, if the downstream zone sensor isblocked, the operating state of the local zone is OFF, or else theoperating state of the local zone is ON. This traditional mode is alsoknown as 1-Zone accumulation logic, or colloquially as “singulation.” Asa result of this traditional 1-Zone accumulation logic, on a conveyorwith a high density of boxes, the boxes flow through zones (which areturning on and off due to the above described traditional logic,blocking eyes or sensors, turning off, but then coasting past those eyesor sensors, causing the zones to turn back on) which starts to combineproduct into zone-size groups with an equal zone-size gap between eachproduct group. Accumulation conveyors configured to utilize suchtraditional accumulation modes, which rely solely on the status of thefirst downstream zone sensor, are unable to decipher between whenproduct is accumulating versus flowing. For example, in an instancewhere a product is just passing through a first downstream zone, suchfirst downstream sensor may indicate that it is blocked. A blockedsensor may indicate that the associated zone is occupied.

Some embodiments of the present disclosure address the above-describeddisadvantages through an improved fundamental mode of operation,sometimes referred to or known in the industry as a type of‘accumulation logic’ that can be performed via a circuit or software.The present disclosure can be used to implement such a control scheme,such as implemented by controller 16, that determines or sets a zoneoperating state or an operating mode associated with an individual zonebased on the existence or satisfaction of two or more conditions orvariables.

Referring to FIG. 3, an improved accumulation logic 20 is shown, whichmay be applied to one or more zones of a plurality of zones of anaccumulation conveyor 2. The individual zone that the accumulation logic20 is examining or configuring is referred to herein as the local zone.In some embodiments, accumulation logic 20 may examine each of theplurality of zones, beginning with the zone which is furthest downstreamof the plurality of zones and progressing upstream, which may beprogressing consecutively upstream examining each zone, or which may beprogressing sequentially upstream potentially skipping zones but stillprogressing in the upstream direction. In the embodiment depicted,accumulation logic 20 begins with the discharge zone, which is zone 12 aof accumulation conveyor 2 of FIG. 1, and ends with the infeed zone, theupstream-most zone of the plurality of zones, which is zone 4 a ofFIG. 1. In some embodiments, the improved accumulation logic 20 used tocontrol the accumulation conveyor 2 is encompassed by multipleintegrated or discrete physical devices. In still further embodiments,the number of zones analyzed may only be a subset (e.g., 1, 2, 3, etc)of the total plurality of zones forming the accumulation conveyor 2.

In accordance with one embodiment, a zone operating state associatedwith a local zone is set to inactive (e.g., OFF) in an instance where anitem detection variable and an operational characteristic variableassociated with a downstream zone are both satisfied. For example, thesystem is configured such that the status of the first downstream zonesensor and the operating state of the first downstream zone are used toconfigure the zone operating state of the local zone. Such downstreamzone sensor data and downstream zone operating state are used tooptimize or improve the overall operational performance of theaccumulation conveyor 2. Zone sensor data is utilized to determinewhether the zone associated with the selected sensor is occupied. Asused herein, a zone is considered occupied when the sensor associatedwith that zone has given a signal indicating detection of an article(e.g., a blocked signal from a photo eye) for a period of time equal toor greater than a first delay period. The first delay period could be,for example, zero, 0.75 seconds, 1.0 seconds or 1.5 seconds. A zonewhich is considered occupied will be considered not occupied once thesensor is cleared (e.g., a photo eye is not blocked) for a period oftime equal to or greater than a second delay period. The second delayperiod could be equal to or different from the first delay period, andcould also be, for example, zero, 0.75 seconds, 1.0 seconds or 1.5seconds. In some embodiments, an item detection variable is satisfiedwhen the zone sensor data indicates the associated zone is occupied. Forexample, an item detection variable associated with a downstream zone issatisfied when a presence of an object on the conveyor is detected viathe one or more sensors associated with the downstream zone.

In one embodiment, the accumulation logic 20 sets the initial oroperational bias of each zone as enabled or active (e.g., ON or sendcontrol signals to the associated zone control module to activate ordrive the one or more rollers associated with such zone) unless anexception is satisfied. For example, the system is configured such thatthe default zone operating state of the local zone is ON unless thefirst downstream zone is actually accumulated or flow has been impededor jammed. In some embodiments, the controller 16 receives firstdownstream zone data comprising zone sensor data and zone operatingstate for the first downstream zone to the local zone. Thus, if the zonesensor data corresponding to an item detection variable indicates thatthe first downstream sensor is occupied (e.g., a blocked signal forrequisite amount of time) and the zone operating state corresponding toan operational characteristic variable indicates that the firstdownstream zone's operating state is OFF, the zone operating state ofthe local zone is set to OFF or otherwise configured as inactive.

Additionally or alternatively, the zone operating state associated witha local zone is set to inactive (e.g., OFF) in an instance where an itemdetection variable associated with a downstream zone and an operationalcharacteristic variable associated with the local zone are bothsatisfied. For example, the system is configured such that the status ofthe first downstream zone sensor and the status of the local zone'sroller countdown timer are used to configure the zone operating state ofthe local zone. In some embodiments, in an instance wherein theoperating state of an individual zone is set to OFF, a roller countdowntimer is initiated and configured to count down from some value (e.g.,zero, 1.5 seconds, 2.0 seconds, 2.5 seconds) to expiration (e.g., lessthan or equal to zero). The value is assigned such that the rollersshould roll to a stop before expiration of the timer which may vary fromzone to zone and conveyor to conveyor. The roller countdown timerensures that the rollers associated with the selected zone have actuallystopped rotating/spinning, as rollers continue to rotate for a period oftime after the operating state of the associated zone is turned OFF andmechanical or pneumatic driving means are no longer supplied to suchrollers. In further embodiments, the roller countdown timer is reseteach time the operational state of the associated zone is set to ON. Instill further embodiments, an individual zone's roller countdown timerbegins to count down once the associated zone is set to OFF. In someembodiments, an item detection variable is satisfied when the zonesensor data indicates that the first downstream zone is occupied (e.g.,a blocked signal from a first downstream zone sensor for a requisiteamount of time) and an operational characteristic variable associatedwith the local zone is satisfied when the local zone's roller countdowntimer has expired. In such embodiments, the zone operating state of thelocal zone is set to, or configured as, OFF. This embodiment allows foraccumulation of product and ensures that upon restart, if the zoneoperating state of the local zone is OFF, it remains OFF unless anduntil the controller 16 sends a signal directing such local zone tostart or to turn ON or the variable conditions change. In someembodiments, instead of analyzing the status of the first downstreamzone sensor and the status of the local zone's roller countdown timer toconfigure the operating state of the local zone, the controller 16 isconfigured to allow for adjustment of a release rate timer as discussedfurther below.

In still further embodiments, the zone operating state of the local zoneis set or configured based upon both the status of the first downstreamzone sensor AND either the status of the first downstream zone'soperating state OR the status of the local zone'sroller-countdown-timer). For example, in some embodiments, if adownstream zone's sensor is blocked AND (the downstream zone's operatingstate is OFF OR the local zone's roller-countdown-timer <=0) then thelocal zone's zone operating state is set to OFF, else the local zone'soperating state is set to ON. For example, the system is configured suchthat determining the zone operating state of the local zone may be basedupon at least determining whether an item detection variable associatedwith the first downstream zone sensor is satisfied and determiningwhether at least one of two operational characteristic variables issatisfied. In some embodiments, a first operational characteristicvariable is associated with the first downstream zone and is satisfiedin an instance where the zone operating state of the first downstreamzone is inactive or OFF. In some embodiments, a second operationalcharacteristic variable is associated with the local zone and issatisfied in an instance where the local zone's roller countdown timeris expired. Thus, in some embodiments, each zone location's operationalbias is ON except for the following situations: OFF if downstream sensoris blocked AND downstream mode is OFF; and OFF if downstream sensor isblocked AND local roller-countdown-timer is expired (where theroller-countdown-timer counts down from some value any time it'srespective zone's operational state is OFF, and gets reset every timethe operational state is ON, which ensures an OFF zone stays off exceptfor a sensor change on release).

In some embodiments, the status of the downstream zone operating stateand the status of the local zone roller countdown timer are consideredzone status data. Thus, in some embodiments, an operationalcharacteristic variable is satisfied when the zone status data indicatesthe downstream zone is OFF or inactive. In still further embodiments, anoperational characteristic variable is satisfied when the zone statusdata indicates the local zone's roller countdown time is expired. Upondetermining the zone operating state associated with the local zone isto be set to inactive in an instance where both the item detectionvariable and at least one operational characteristic variable aresatisfied, a command signal with the appropriate inactivation signal istransmitted to a control module associated with the respective localzone. A table further setting forth this logic is demonstrated in Table1.

TABLE 1 Local Zone Downstream Downstream Status of Local Operating ZonePresence Zone Operating Zone Roller State Detected State Countdown TimerON FALSE OFF EXPIRED (≤0) ON FALSE OFF NOT EXPIRED (>0) ON FALSE ONEXPIRED (≤0) ON FALSE ON NOT EXPIRED (>0) ON TRUE ON NOT EXPIRED (>0)OFF TRUE OFF EXPIRED (≤0) OFF TRUE OFF NOT EXPIRED (>0) OFF TRUE ONEXPIRED (≤0)

The disclosed accumulation mode can decipher between when product isaccumulating vs. flowing using the basic idea “if downstream is going,then go full speed” and its net effect with each zone doing this sametest keeps the flow going. In the embodiment shown in FIG. 3,accumulation logic 20 is re-executed for the next upstream zone,continuing until all zones have been examined. In other embodiments, theaccumulation logic 20 is executed with respect to one or more zones, butnot necessarily all of the zones of an accumulation conveyor 2. In stillfurther embodiments, the accumulation logic 20 is tested continually,beginning at the discharge zone again. This separation of accumulationvs. release finally allows certain combinations of product handling androutes to co-exist naturally, without having the same level oftrade-offs that have existed in the past and without stackingoperational modes. Costs savings through less setup, more operationalefficiency and performance to customers is achieved. Accordingly, on aconveyor with a high density, the boxes flow through the zones (that areno longer turning on and off) meaning the infeed stays full speed, andaccumulation only occurs where it's actually accumulated (off andblocked).

Additionally or alternatively, in still other embodiments, it iscontemplated that the zone operating state of the local zone is set toOFF if the first downstream sensor is blocked AND local zone number isless than or equal to X, wherein X is some value greater than or equalto 1 and represents the number of zones to which this aspect of theaccumulation logic 20 may be applied. Such embodiments prevent runawayon release. For example, the system is configured such that the statusof the local zone's first downstream zone sensor and a comparison of thelocal zone's assigned zone number to a threshold range may be used toconfigure the operating state of the local zone and allow for release ofproduct zone by zone, or groups of zone by groups of zones in someembodiments, instead of all at once. Accordingly, in some embodiments,the zone operating state associated with a local zone is set to inactiveor OFF in an instance where an item detection variable associated with adownstream zone and an operational characteristic variable associatedwith the local zone are both satisfied. In some embodiments, anoperational characteristic variable associated with the local zone issatisfied when the zone status data indicates the local zone number isless than or equal to X. For example, in some embodiments, to empty outan accumulation conveyor 2, the controller 16, applying the accumulationlogic 20, sends a release signal to the zone control modules. Therelease signal enables, activates, otherwise turns ON the furthestdownstream zone. This zone is assigned a local zone number of one (localzone number=1). To avoid releasing all zones at once which may result ina product runaway on release, in some embodiments, the controller 16,applying the accumulation logic 20, proceeds to assign a local zonenumber to each zone in a plurality of zones upstream of local zonenumber one, progressively increasing by one for each zone upstream fromsuch zone. For example, in some embodiments, as the product in localzone number one proceeds downstream on the accumulation conveyor 2 inresponse to receiving a release signal, the other zones assigned localzone numbers equal to or less than X will remain in OFF mode, unless anduntil the status of the first downstream sensor to the particular localzone indicates that it is no longer blocked or occupied. A table furthersetting forth this logic is demonstrated in Table 2.

TABLE 2 Local Zone Downstream Zone Local Zone Operating State PresenceDetected Number ON (unless an embodiment FALSE Local Zone comprisesother Number > X applicable logic defining the local zone operatingstate) ON (unless an embodiment TRUE Local Zone comprises other Number >X applicable logic defining the local zone operating state) ON (unlessan embodiment FALSE Local Zone comprises other Number ≤ X applicablelogic defining the local zone operating state) OFF TRUE Local ZoneNumber ≤ X

Accordingly, in some embodiments wherein the local zone number of alocal zone is greater than X, the zone operating state of such localzone is set to active such that the local zone is ON. In certainembodiments, the zone operating state of the local zone may otherwise besubject to other control logic parameters. In a non-limiting exemplaryexample wherein X is 5 and the local zone number is determined to be 9,if the embodiment employed only the above identified local zone numberlogic, the zone operating state of the zone associated with local zonenumber 9 would be set to active such that local zone number 9 is ON. Inanother non-limiting example wherein additional accumulation logic isemployed, such as a status of a downstream sensor and zone operatingstate of the first downstream zone, the zone operating state of the zoneassociated with local zone number 9 would be dependent not on the aboveidentified local zone number logic, but rather logic relying upon astatus of a downstream sensor and the zone operating state of the firstdownstream zone, such as set forth in Table 1. The provided examples arenon-limiting and it is contemplated that a zone or plurality of zonesmay be subject to one or more control logic embodiments disclosedherein.

In some embodiments, instead of analyzing the status of the firstdownstream zone sensor and the local zone number to configure or set thezone operating state of the local zone, the controller 16 is configuredto allow for adjustment of a release rate timer as discussed furtherbelow.

Additionally or alternatively, in still further embodiments, it iscontemplated that the zone operating state of the local zone is set toOFF if the local zone is blocked and the downstream zone'spre-jam-countdown-timer is less than or equal to zero (pre jam timer<0), thereby effectively dropping or adjusting the accumulation logicapplied to the local zone to a traditional 1-Zone accumulation logic,while allowing a potential jam downstream to clear and lowering the backpressure on a real jam so that such jams may be dislodged easier. Insome embodiments, the system is configured such that the zone operatingstate of the local zone is set to OFF when a potential jam immediatelydownstream is detected. Accordingly, in some embodiments, the zoneoperating state associated with a local zone is set to inactive suchthat the local zone is turned OFF in an instance where an item detectionvariable associated with the local zone and an operationalcharacteristic variable associated with the downstream zone are bothsatisfied. For example, an item detection variable associated with thelocal zone is satisfied when a presence of an object on the conveyor isdetected by one or more sensors associated with the local zone.Additionally, in some embodiments, an operational characteristicvariable associated with the downstream zone is satisfied when the zonestatus data indicates a pre jam timer associated with the downstreamzone is expired (e.g., less than or equal to 0). A table further settingforth this logic is demonstrated in Table 3.

TABLE 3 Status of Local Zone Operating State Downstream PreJam Timer ON(unless embodiment NOT EXPIRED (>0) comprises other applicable logicdefining the local zone operating state) OFF EXPIRED (≤0)

In some embodiments, a local zone's prejam timer begins to count downfrom a predetermined value each time its first downstream zone's sensoris not blocked AND the local zone's own sensor is blocked AND the localzone's first upstream sensor is blocked. For example, the local zone'sprejam time may be activated in an instance where the first downstream'szone sensor is not blocked and the local zone's sensor and the localzone's first upstream sensor are both blocked. In still furtherembodiments, the local zone's pre jam timer gets reset in every othercondition. For example, a local zone's pre jam timer is configured toactivate each time zone sensor data indicates that item detectionvariables associated with each of the local zone and a first upstreamzone are satisfied and an item detection variable associated with afirst downstream zone is not satisfied. In some embodiments, a pre jamcountdown timer is assigned a value (e.g., 2.5 second, 3.5 seconds, 5seconds, or an amount of time pre-calculated to correspond to the timeit takes product to traverse a certain number of zone lengths at fullspeed) from which it counts down to expiration (e.g., <=0). A tablefurther setting forth this logic is demonstrated in Table 4.

TABLE 4 Status of Downstream Local Zone Upstream Local Zone ZonePresence Presence Zone Presence Prejam Timer Detected Detected DetectedCOUNTDOWN FALSE TRUE TRUE RESET ALL OTHERS

Accordingly, in certain embodiments, the pre jam timer associated with azone is initiated or activated in instances wherein the first downstreamsensor is NOT blocked AND the local sensor is blocked AND the firstupstream sensor is blocked. In still further embodiments, the pre jamtimer is reset in every other condition. In such embodiments, the zoneoperating state of a local zone is set to OFF when the pre jam timerassociated with the first downstream zone has expired. For example, whenthe pre jam timer associated with the first downstream zone is less thanor equal to zero, the zone operating state of the local zone isinactivated. In such instances, a jam may be occurring in such firstdownstream zone. For example, the controller 16 detects a jam may beforming in this embodiment because sensors associated with each of thelocal zone and the first upstream zone indicate they are occupiedwithout detecting any gap between product (e.g., blocked for extendedperiod of time), however, the first downstream zone may be ON but withno product flowing. The pre jam timer is initiated upon detection ofthis situation and upon expiration of such timer, the first zoneupstream of the potential jam is turned OFF. In some embodiments, theaccumulation logic 20 reverts to the traditional 1-Zone or singulationmode of accumulation in this instance, relying on only the status of thefirst downstream sensor to determine the zone operating state of thelocal zone. In such instances, the zone operating state of the localzone will be enabled, activated, or otherwise turned ON once the firstdownstream sensor is not blocked.

In some embodiments, if the local zone being examined is the dischargezone or the most downstream zone physically, the accumulation logic 20may be configured such that an additional virtual zone is establisheddownstream of the discharge zone wherein the status of the virtualsensor associated with the virtual zone is defined as occupied andblocked, the zone operating state of the virtual zone is defined as OFFsuch that it is not actively running, and the virtual zone's downstreamzone is defined as itself. Such a virtual zone with defined itemdetection variables and operational characteristic variables improvesthe accumulation logic 20 in some embodiments.

Additionally, although embodiments discussed herein generally disclosean improved, smarter version of 1-Zone accumulation or singulation, itis contemplated that the disclosed embodiments may apply to any othertraditional types of accumulation mode, such as 0&1-Zone accumulationlogic, 1&2-Zone accumulation logic, 2-Zone accumulation logic, etc.,with appropriate modifications. For example, an improved 0&1-Zoneaccumulation logic may be configured to determine whether a first itemdetection variable associated with a first zone (e.g., local zone) issatisfied, whether a second item detection variable associated with asecond zone (e.g., a downstream zone) is satisfied, and whether at leastone of two operational characteristic variables is satisfied, and in aninstance where both the item detection variable and at least oneoperational characteristic variable are satisfied, set a zone operatingstate associated with the first zone to inactive. In an exemplary,non-limiting example, an accumulation conveyor applying such an improved0&1-Zone accumulation logic may be configured to stop or otherwise turnOFF a local zone if the sensor associated with the local zone is blocked(e.g., the 0-zone is blocked), the sensor associated with the firstdownstream zone is blocked (e.g., the 1-zone is blocked) and at leastone operational characteristic variable, such as the zone operatingstate of the downstream zone is OFF, is satisfied.

As indicated above, existing efforts to adjust the aggressiveness ofaccumulation of product have proven to be complicated and non-intuitive.Adjusting the aggressiveness of accumulation adjusts how hard or softproduct hits other product as its slowing down on a conveyor. Thedetermination of which operational mode or combination or “stack” ofoperational modes will result in more or less aggressiveness thananother mode or configuration of modes has traditionally been difficultand prone to error. Accordingly, additionally or alternatively, inanother embodiment, an accumulation conveyor can be configured to havetunable accumulation aggressiveness. As such, this present disclosurediscloses an example method to adjust the aggressiveness of accumulationsimpler using a tuner. The tuner allows for cost savings, in someexamples, through less setup, and more operational efficiency and betterperformance is achieved.

Some example embodiments of the present disclosure achieve thesebreakthroughs through an aggressiveness configuration interface referredto as a wizard in some examples, that asks questions in order to obtaininitial values and/or settings (from a lookup table) and then transfersthose values into a linear equation controlled by a user-adjustmentmechanism. This mechanism stacks or combines one or more operationalmodes to form a linear, consistent sequence of values which isconfigured to make accumulation increasingly harsh in one direction andincreasingly soft in the other direction, sometimes changing oradjusting multiple values (e.g., 7) at once.

In one embodiment, an accumulation conveyor 2 may be associated with anaggressiveness configuration interface. In some embodiments, theaggressiveness configuration interface is configured such that it allowsusing the conveyor data input received from a user in response toquestions found in the configuration interface, to define certainconfiguration variables, such as Conveyor Speed, Average Zone Length,Type of Package, Average Package Weight (for Live Load), etc. In anon-limiting exemplary example, certain embodiments comprise outputtingor rendering an aggressiveness configuration interface to a controlleruser interface associated with the controller 16, wherein theaggressiveness configuration interface comprises an interactiveinterface configured for user engagement via the controller userinterface. In some embodiments, the interactive interface is configuredfor displaying queries and receiving user data input in response to suchqueries. According to various embodiments, the controller user interfaceassociated with the controller 16 may be any type of display or userinterface capable of portraying data associated with the controller 16such as the display of a smart phone, tablet computer, laptop computer,wearable, personal computer, and the like. Such an aggressivenessconfiguration interface can be provided via software in someembodiments. The confirmation interface can be provided via hardware inother embodiments. The configuration interface can be provided via acombination of software and hardware in still further embodiments.

Combined with standardized lookup tables, in some embodiments, theaccumulation conveyor 2, such as via the controller 16, is configured toanalyze the received conveyor data input and query an accumulationsettings repository for accumulation settings based upon at least theconveyor data input. That is, the controller 16 receives conveyor datainput associated with user engagement of the aggressivenessconfiguration interface and queries an accumulation settings repositorybased upon at least the conveyor data input. The accumulation settingsrepository comprises aggressiveness parameters including, but notlimited to, acceleration values, deceleration values, zone length,neighborhood size, accumulation models, prior accumulation installationmodels, etc. In some embodiments, the accumulation setting repositorycomprises an application guideline, which demonstrates recommendationsfrom prior installations experience and models of product behavior, inorder to determine which parameters should be enabled or disabled (suchas Neighborhood Mode, Dynamic AutoSlug), what Acceleration andDeceleration should be set to, what Zone Length should be set to, andcalculate the size of the Neighborhood to otherwise determine how manyzones would be pulsing (e.g., turning ON and OFF) behind or upstream ofan accumulated zone. Also, based on the above conveyor data input(namely Avg Zone Length) and the Accumulation Aggressiveness Slidervalue, the accumulation mode (e.g., accumulation logic) isauto-selected.

Based upon at least the accumulation settings returned by the query andthe conveyor data input, the controller 16 determines an initialaccumulation mode. Based upon the accumulation settings returned by thequery, the controller 16 programmatically generates an aggressivenesslinear equation and assigns an aggressiveness value associated with theinitial accumulation mode as a default value of the linear equation.

In a further non-limiting exemplary example, the controller 16 furtherconfigures an aggressiveness interface object 501 based upon at leastthe aggressiveness linear equation and the assigned default value andrenders or outputs the aggressiveness interface object 501 to thecontroller user interface. In some embodiments, the aggressivenessinterface object 501 is a user-adjustable mechanism such as a slidingtuner, that is configured to increase and decrease the aggressiveness ofthe accumulation in accordance with and in response to detecting userengagement of the user-adjustable mechanism. In such embodiments, thesystem may be configured such that it includes an adjuster/slider foraggressiveness. For example, the neighborhood size determined inassociation with the aggressiveness configuration interface or wizardmay be set to the “Accumulation Aggressiveness” slider value of 50, theslider value ranging from 0-100. In such example embodiment, theconveyor system is configured to treat packages softer on accumulationby lowering the slider value or harsher on accumulation by increasingthat slider value. The system is configured such that the user is ableto adjust the aggressiveness of the impact of the accumulation on asliding scale to which the user can relate in a linear fashion asopposed to attempting to configure and stack multiple operational modes,some of which are logarithmic and thus are less intuitive whenattempting to increase or decrease aggressiveness. The aggressivenessinterface object 501 is depicted as a user-adjustable mechanism in aslider formation in FIG. 5, but other configurations are alsocontemplated, including but not limited to, a physical knob, up/downindicators, digital display, keystroke entry, or any other configurationthat can be rendered, expressed, or provided in a physical, touchablecontrol.

In some embodiments, it is contemplated that the default accumulationmode is set to the improved and smarter 0&1-Zone accumulation logiccorresponding to the present disclosure, which compacts product well butis also more aggressive. In such embodiments, in an instance wherein theuser-adjustable mechanism associated with accumulation aggressiveness isadjusted below a minimum aggressiveness threshold, the controller 16reverts to the improved, smarter, and less aggressive 1-Zoneaccumulation logic described herein in an effort to ensure the productis slowed down accordingly.

In still other embodiments, it is further contemplated that in instanceswherein the user-adjustable mechanism associated with accumulationaggressiveness is adjusted below a minimum regulator threshold, thecontroller 16 adjusts, to a lower value, the minimum time that an airregulator is on (e.g., MinRegOn) so that the pneumatic actuators drivingthe rollers are able to pulse on for lesser amounts of time, therebylessening the aggressiveness of such accumulation.

In some embodiments, the neighborhood size can be adjusted as a resultof changes in the settings or value of accumulation aggressiveness. Forexample, in some embodiments, the accumulation conveyor 2 uses datainput by a user or variable(s) determined by the controller itself tocalculate the initial size of a neighborhood, such as v1_nhood_size,according to a traditional or original neighborhood mode algorithm. Forexample, in some embodiments, the neighborhood size is determined basedupon at least the length of zones, acceleration and deceleration values,etc. In still further embodiments, an accumulation conveyor 2, such asvia the controller 16, can determine or adjust the neighborhood sizeusing alternative neighborhood v2 algorithms. In some embodiments, thesize of the determined neighborhood can be adjusted based on the sliderusing such variables as hardest_mult (corresponding to a multipliervalue), hardest_tick (corresponding to the highest tick mark or value ona slider), min_adder (corresponding to an additive value),accum_delay_max, and accum_delay_min_adder (corresponding to an additivevalue), one or more of which may be found in a lookup table. Thisimproved method for calculating the neighborhood size stops using thetraditional or original neighborhood mode algorithm directly, andinstead labels each zone upstream of an accumulated zone an index numberup to the neighborhood size. For example, as the aggressiveness islowered, the size of the neighborhood is increased such that the speedsof additional zones upstream of the local zone are configured to allowfor the product to slow down sooner and over a greater distance, therebyresulting in a softer impact of product as it comes to a stop. In suchinstances, more upstream zones are pulsing or otherwise acceptingcontrol as part of the determined neighborhood. In instances where theaggressiveness is increased, the size of the neighborhood is decreasedsuch that less zones are pulsing. Thus, in some embodiments, in responseto detecting an indication to adjust the aggressiveness level of theaccumulation conveyor 2, the controller 16 is configured toprogrammatically adjust the speeds or rates of one or more zonesupstream of the local zone. In still further embodiments, in response todetecting an indication to decrease the aggressiveness level of theaccumulation conveyor, the controller 16 is configured toprogrammatically lower the speeds or rates of one or more zones upstreamof the local zone. In still further embodiments, in response todetecting an indication to increase the aggressiveness level of theaccumulation conveyor, the controller 16 is configured toprogrammatically increase the speeds of one or more zones upstream ofthe local zone.

To determine the appropriate speed setting for one or more upstreamzones in a neighborhood, some embodiments comprise querying speedparameters associated based upon at least the index number. For example,the index number may then be used to retrieve a respectivepre-calculated linear speed_factor value (or percentage of full_speed)for that associated index number. For example, in some embodiments, theaccumulation conveyor 2 determines a speed, or rate of velocity, for aselected zone by multiplying that retrieved speed_factor value by thatselected zone's max speed, then put in the zone's Speed Regulator, andeach of the neighborhood zones comprising a valid or associated indexvalue are now pulsing. A speed regulator associated with a zone can beused in some embodiments to calculate a periodic duty cycle to vary theON-time (e.g., activated) and OFF time (e.g., deactivated) of a constantspeed driving mechanism in a conveyor, such that the percentage ofapplied driving force to the one or more rollers in a zone is varied inorder to alter the speed of the product on the one or more rollers.

In some embodiments, for certain harsher slider values when theneighborhood size is zero (0), a zone that normally would shut OFF dueto accumulation, instead is configured according to a linearlyincreasing accumulation delay value. For example, a linearly increasingaccumulation delay value allows the rollers associated with a zone tostay on a bit more after accumulation, thereby increasing the harshnessof accumulation. For certain softer slider values, in some embodiments,the logic decreases the Speed Regulator's “minimum regulator ON time” inorder to soften the lower speed pulsing effect. In some embodiments, thedecrease is determined linearly. This disclosure contemplates othermethods of decreasing the “minimum regulator ON time,” such aslogarithmically.

Accordingly, in certain embodiments wherein the improved accumulationlogic 20 comprises the adjusted neighborhood size and linearlyincreasing accumulation delay embodiments described herein, the adjustedneighborhood size and the accumulation delay, v2_nhood_size andaccum_delay respectively, may be determined based upon an associatedvalue of the Accumulation Aggressiveness adjustable mechanism or slider.In a non-limiting example, if the sum of the initial neighborhood sizedetermined under the traditional or original neighborhood mode algorithmand a knob factor that depends on the value of accum_slider_tick, whichis the associated value of the Accumulation Aggressiveness adjustablemechanism or slider is greater than or equal to 0, the adjustedneighborhood size may be calculated as the sum of the initialneighborhood size and the whole number ceiling of the knob factor value.In such an embodiment, the accumulation delay may be defined as 0. In afurther non-limiting example, if the sum of the initial neighborhoodsize and the knob factor is less than 0, the adjusted neighborhood sizemay be defined as 0 and the accumulation delay may be determined basedupon one or more variables, such as delay time at speed, delay speed,lane speed ips (wherein speed may be measured in inches per second insome embodiments), hardest tick, start accum tick and accum slider tick.By way of non-limiting example, determining the accumulation delay valueis given by the following formula:accum_delay=((delay_time_at_speed*delay_speed)/lane_speed_ips)/((hardest_tick−start_accum_tick)*(accum_slider_tick−start_accum_tick))

In some embodiments, the knob factor is associated with the value of theassociated value of the Accumulation Aggressiveness adjustable mechanismor slider (i.e., accum_slider_tick). In such embodiments, a start accumdelay tick is assigned the slider tick value at which the accum delaystarts being applied to a particular zone. By way of non-limitingexamples, determining the knob factor value and the accum delay starttick value, respectively, are given by the following formulas:knob_factor=[(accum_slider_tick−(hardest_tick/2))*hardest_mult*2]/hardest_tickaccum_delay_start_tick=(hardest_tick/2)+accum_delay_min_adder−[(hardest_tick*v1_nhood_size)/(hardest_mult*2)]

In still further embodiments, the speed or speed at index associatedwith an indexed zone associated with the adjusted neighborhood size andlocated upstream of an accumulated local zone can be determined. Forexample, in a non-limiting embodiment, if the speed denominator is equalto 0 OR a calculated speed at index is greater than lane speed measuredin inches per second OR a calculated speed at index is less than 0, thespeed at index may be set to the lane speed measured in inches persecond. In still further embodiments, the speed at index may be set tothe calculated speed at index. By way of non-limiting examples,determining the calculated speed at index and the speed denominator,respectively, are given by the following formulas:calculated_speed_at_index=lane_speed_ips*(zone_nhood_index+min_adder)/speed_denominatorspeed_denominator=v1_nhood_size+knob_factor+min_adder+1

In a non-limiting exemplary embodiment, the accumulation conveyor 2 maystore certain variables at defined values. For example, hardest_tick,corresponds to or represents the highest tick mark on an associatedslider and may be set to any value. For example, in some embodiments,the hardest_tick may be set to 100. In some embodiments, hardest_mult isa multiplier and may be set to any value. For example, in someembodiments, the hardest_mult may be set to −7.5. In still furtherembodiments, min_adder and accum_delay_min_adder are each additivevalues. In some examples, min_adder may be set to 2 andaccum_delay_min_adder may be set to 5. In certain embodiments,accum_delay_at_speed is the amount of time, measured in seconds, that ittakes for a particular type of roller/bearing combination to spin downat accum_delay_speed. In another non-limiting exemplary embodiment,accum_delay_at_speed may be set to 2 seconds and accum_delay_speed maybe set to 48 inches per second.

In other embodiments, it is contemplated that for certain areas of theconveyor that are known to accept mini-slugs of product or groupings ofX number of zones worth of product, the number of zones with the sameindex can be extended to X+gap worth of zones, until it moves onto thenext index with its own respective X+gap worth of zones, etc up toneighborhood size. For example, in some embodiments, a mini-slug ofproduct may span more than one zone. In such instances, the controller16 is configured to adjust the speed of upstream zones by groups ofzones instead of just by individual zone. For example, an index numbermay be associated with one or more zones.

In another embodiment, a release rate tunable accumulation conveyor isdisclosed. The release rate is a function of the amount of inserted gapin between each zone as it releases. Traditionally, there is no easy wayto tweak the release rate of an accumulation conveyor into whatever isdownstream (whether it be a merge or another conveyor going at differentrates) without also negatively affecting how it accumulates and handlesproduct. The traditional method to adjust the release rate is to changethe accumulation mode to change the release rate, or add some of theother stackable features found in products such as ZoneFlex® Advanced,but those modes and features interfere with each other's purposes (someare for release, but affect accumulation, or vice versa). For example,in traditional accumulation conveyors, the release rate is notseparately adjustable from the accumulation aggressiveness. Today, aconveyor, and the logic surrounding it, does not know the differencebetween zones that are releasing or accumulating.

In some embodiments, the accumulator conveyor can pre-calculate one ormore release rate sliders that are user adjustable (in hardware orsoftware), where the value relates to the rate (e.g., possibly inpercentage) that the user wants the conveyor to release at. For example,in one embodiment, the tunable release rate accumulation conveyor canhave an interface with one or more user adjustable sliders or knobs thatchange the amount of gap between the release of each zone (by using atimer configured by the configured speed of the conveyor when engaged)so that it directly and linearly changes the ‘carton feet per minute’that releases from the accumulation conveyor. For example, in someembodiments, the controller 16 is configured to render or output one ormore release rate interface objects 601, i.e., user-adjustablemechanisms such as a sliding tuner, to the controller user interfacethat are configured to increase and decrease the release rate inaccordance with and in response to detecting user engagement of theuser-adjustable mechanisms. The exemplary release rate interface objectof FIG. 6 is depicted as a slider, but other configurations are alsocontemplated, including a knob, up/down indicators, digital display,keystroke entry, etc. Thus, in some embodiments, in response todetecting an indication to adjust the release rate level of theaccumulation conveyor (e.g., via the release rate interface object 601),the controller 16 is configured to generate a release rate timer basedupon at least a configured speed of the corresponding zone. Theaccumulation conveyor 2, via the controller 16, only releases the nextupstream zone upon expiration of the release rate timer. In anexemplary, non-limiting example, a slider value of 50% will equate to atimer that inserts 36 in of gap after releasing a 36 in zone of productand before releasing the next zone, where a slider value of 100% willhave 0 in of gap between each zone. In embodiments using percentages,the controller 16 configures the release rate timer (e.g.,smart_release_scans time) by converting the user input received via useradjustment of the Release Rate slider into how much time in between eachzone's releases to equal that percentage of release rate. In oneexemplary, non-limiting embodiment, if it takes 0.95 secs for a zonelength of product to pass through a zone at the conveyor's full speed,and the slider is set to 75% release rate, then gap is calculated to be0.32 seconds. That is, 0.95 s/0.75-0.95 s)=0.32 sec. Although slidervalue percentages are discussed, other configurations are alsocontemplated by this disclosure including a direct relation to cartonfeed per minute or a generated sliding scale. In some embodimentswherein the improved accumulation logic 20 and the release logic areboth employed, the release logic may replace and/or override the portionof the accumulation logic 20 related to the roller countdown timer thatprevents runaway on release. In such embodiments, the system isconfigured such that the release logic controls the release rather thanthe roller countdown timer controlling the release.

In some embodiments, the accumulator conveyor 2 also has the optionalability to estimate the amount of air/compaction already present in eachzone as it's being released, so that, on the fly, it adjusts the nextgap upstream so as to best meet the rate requested, even in the part ofthe zone that is not monitored by the sensor (that is located downstreamof it).

In some embodiments, the accumulator conveyor 2 is also configured tohave the optional ability for a user to delineate different areas ofzones of the conveyor that associate with each of these Release Ratesliders. For example, the system is configured such that the controller16 configures the accumulation conveyor to have the ability to have morethan one area where release rate is different. For example, a user maydesire to have a faster rate toward the discharge, but more gap toaccumulate nicer upstream handling.

In still further embodiments, the accumulator conveyor is alsoconfigured to have the ability to release in groups in certain areas,but not in others. For example, it may be helpful in keeping mixedproduct together when re-indexing them forward (most problems comes fromaccumulation, so said product is just moving forward a few zones, thenit's better to keep the already accumulated product as a group, and movethe whole group together). As such, in some embodiments the userdelineates these different areas controlled by different Release Ratesliders to have different size groupings of zones that release togetheras if they are one big zone, and which all zones except the mostdownstream have their smart_release_scans time set to 0 sec (meaning itreleases with the downstream zone together).

In still further embodiments, the accumulator conveyor 2 may label orotherwise identify each zone if the smart_release_scans time is lessthan the standard time it takes for the tail of product in a zone turnedon to reach the photoeye. For example, such zone may be identified ashaving a pre-photoeye release. If smart_release_scans time is more thanthat standard time it takes for the tail of the product to reach thephotoeye in that zone, the system may be configured to identify suchzone as having post-photoeye release. For example, the system isconfigured such that the controller 16 is configured to determinewhether the release rate timer (e.g., smart_release_scans time) is lessthan the standard time it takes for the tail of product in an enabled,activated, or otherwise turned ON zone to reach the photo eye sensor. Ifthe controller 16 determines that the release rate time is less than thestandard time, the controller identifies such zone(s) as a pre-photoeyerelease. If the controller 16 determines that the release rate time ismore than the standard time, the controller identifies such zone(s) as apost-photoeye release.

In such embodiments where it is determined that the release rate time ismore than the standard time it takes for the tail of the product toreach the photo eye sensor (e.g., a post-photo release zone), thecontroller 16 is configured to estimate the amount of air or gapsbetween product in the whole zone (e.g., small amount of air/gapssignals higher compaction) by using part of the zone that the productwill pass through as a likely model of the whole zone's compaction. Thecontroller 16 is configured to monitor the amount of time the subjectzone's sensor is blocked or clear and extends or extrapolates that ratioto the rest of the zone that the sensor is not able to monitor due toits positioning

In some embodiments, release logic is applied to one or more zones of aplurality of zones of an accumulation conveyor 2. As with theaccumulation logic 20 discussed above, the individual zone that therelease logic is examining or configuring is referred to herein as thelocal zone. In some embodiments, the controller 16 is configured to runboth the release logic and the accumulation logic 20. In otherembodiments, the controller 16 is configured to run only accumulationlogic 20. In other embodiments, the controller 16 is configured to runonly release logic.

The release logic is configured such that each zone's operational statebias is ON, however, the release logic is configured to set the zoneoperating state of the local zone to OFF in a number of embodiments. Inone such embodiment, the release logic configures the operating state ofthe local zone to OFF if the local zone is determined to be pre-photoeyerelease, the status of the sensor associated with the local zone isoccupied, the operating state of the first downstream zone is ON, thestatus of the sensor associated with the first downstream zone isoccupied, and the time from when the downstream zone is turned ON isless than the release rate timer associated with the local zone. A tablesetting forth this logic is demonstrated in Table 5.

TABLE 5 Local Zone Local Zone Local Zone Downstream Downstream TimeDownstream Operating Determined Pre- Presence Zone Operating ZonePresence Zone ON < Local Zone State Photoeye Release Detected StateDetected Release Rate Timer OFF TRUE TRUE ON TRUE TRUE ON TRUE FALSE ONTRUE TRUE ON TRUE FALSE OFF TRUE TRUE ON TRUE FALSE OFF FALSE TRUE ONTRUE FALSE OFF FALSE FALSE ON TRUE TRUE OFF TRUE TRUE ON TRUE TRUE OFFFALSE TRUE ON TRUE TRUE OFF FALSE FALSE ON TRUE TRUE ON FALSE TRUE ONTRUE TRUE ON FALSE FALSE ON TRUE TRUE ON TRUE FALSE

In some embodiments, the release logic configures the zone operatingstate associated with a local zone that is further associated with ascan timer, which is activated once a first downstream zone is enabled,activated, otherwise set to ON, thereby pulling product away from thelocal zone, which is still set to OFF and is not moving. In suchembodiments, a zone operating state associated with a local zone isenabled, activated, otherwise set to ON and starts to move in aninstance where an item detection variable associated with the firstdownstream zone is not satisfied AND a scan time value associated withthe local zone satisfies a scan threshold. For example, the system isconfigured such that the status of the first downstream zone sensor andthe scan timer are used to configure the zone operating state of thelocal zone in such embodiments. For example, the scan time valueassociated with the local zone satisfies a scan threshold when the scantime value is greater than or equal to a smart release scan valuedetermined by the accumulation conveyor 2. The smart release scan valuecorresponds to a period of time measured in scans between each zonebeing activated such that a requested rate of the accumulation conveyor2 is obtained. By way of non-limiting example, determining the smartrelease scan value for a local zone is given by the following formula:smart release scan=((hardest_tick−slider release tick)/slider releasetick)*scans per sec*(zone length inches/lane speed ips)In such example, the zone length may be the length of the local zone insome measurement, such as inches.

In still other embodiments, the release logic configures the zoneoperating state of the local zone to OFF if the local zone is determinedto be post-photoeye release, the status of the sensor associated withthe local zone is occupied or blocked, the zone operating state of thefirst downstream zone is ON, and the amount of time corresponding to theair gaps in the zone, which is sometimes referred to as the air_in_zonetime is less than the release rate time associated with the local zone,which is referred to in some embodiments as smart_release time. A tablesetting forth this logic is demonstrated in Table 6.

TABLE 6 Local Zone Local Zone Local Zone Downstream Air Gap Time <Operating Determined Post- Presence Zone Operating Local Zone StatePhotoeye Release Detected State Release Rate Timer OFF TRUE TRUE ON TRUEON TRUE FALSE ON TRUE ON TRUE TRUE OFF TRUE ON TRUE TRUE ON FALSE ONTRUE FALSE OFF TRUE ON TRUE FALSE OFF FALSE ON TRUE TRUE OFF FALSE

In still further embodiments, the release logic is configured todetermine an amount of air between two zones. That is, in someembodiments, the release logic may determine the amount of air between alocal zone and a first downstream zone so as to allow an earlyactivation (e.g., turning ON) of the local zone in certain instanceswhere a lot of air or space is detected downstream of the local zone.For example, in some embodiments, the release logic determines an amountof air between two zones by analyzing a part of a product that isupstream of an active zone's sensor that passes by that active zone'ssensor when it starts moving and associates such determination with anamount of air in the entire active zone. By way of non-limiting example,determining the air in zone scans value is given by the followingformula:air_in_zone_scans=timer_since_downstream_activated_scans+while_active_eye_clear_scans*(1+predicted_air_downstream_of_eye_ratio)

-   -   where:    -   while_active_eye_clear_scans is the amount of time measured in        scans that a zone's sensor detects air such that the sensor is        unblocked for up to the amount of scans that are present for        product to normally pass by it with only the selected zone        activated    -   predicted_air_downstream_of_eye_ratio is a ratio of the distance        downstream of a selected zone's sensor (e.g., photoeye) to the        length of the zone upstream of the same selected zone

By way of non-limiting example, with respect towhile_active_eye_clear_scans, if 24 inches of potential product lengthis upstream of a selected zone's sensor and still within that zone, thesensor associated with that selected zone counts the number of scans forwhich the sensor (e.g., the photoeye), is clear for only the amount oftime associated with 24 inches of such potential product to flowthrough. By way of further non-limiting example, if a selected zone is36 inches in length and a sensor, such as a photoeye, is placed 24inches from the infeed of such selected zone, thepredicted_air_downstream_of_eye_ratio is determined to be 0.5. By way offurther non-limiting example, if a selected zone is 72 inches in lengthand a sensor, such as a photoeye, is placed 24 inches from the infeed ofsuch selected zone, the predicted_air_downstream_of eye_ratio isdetermined to be 2.0.

In still further embodiments, the release logic configures the operatingstate of the local zone to OFF if detectable_gap_exists and the localzone is above or upstream of a slug/release zone and the downstreamsensor has not seen a gap for some value (e.g., zero seconds, 1.5seconds, 2.5 seconds, 5 seconds) greater than or equal to one zonelength of time, then the local zone drops to 1-Zone accumulation suchthat the local zone stops until the downstream zone's sensor becomesclear. This acts as a prejam detector, stops product from overfeeding aslower downstream conveyor/belt, and stops product from connecting to aslug.

In still further embodiments, the release logic is configured such thatit determines that detectable gap exists (e.g., adetectable_gap_existsvariable) by comparing an offset measurement associated with a sensor's,such as a photoeye's, reflector and the smart release scan value. Forexample, in a non-limiting example, if the smart release scan is lessthan the offset measurement associated with a selected sensor (e.g.,after converting to equivalent units), the associated gap in betweenproduct being released is so small, there is little chance of a sensordetecting or identifying a gap. In such an example, the release logicdetermines the detectable_gap_exists variable is set to false. In allother instances, the detectable_gap_exists variable is set to true. In anon-limiting example, when the release rate is set to certain highvalues, such as in instances of slugging wherein the release rate may beas high as 100% release rate, a detectable gap is not expected as allzones set to that release rate value will energize, activate, otherwiseturn ON at the same time, thereby introducing no gap. Without any gap,certain pre-jam detection at the requested rate would be detrimental.Accordingly, in such embodiments, the logic associated with such pre jamdetection is disabled by this embodiment.

In still further embodiments, the release logic is configured such thatit detects prejams and stops product from overfeeding a slowerdownstream conveyor/belt. For example, in some embodiments, theoperating state of the local zone to set to OFF in an instance where agap between slugs is expected but a sensor associated with a zoneupstream of the discharge zone of an accumulation conveyor 2 (e.g., alocal zone) fails to detect a gap between product within a certainamount of time. For example, if a gap detection timer fails to satisfy apredetermined threshold. In some embodiments, if the value of a gapdetection timer associated with detecting a gap is greater than apredetermined amount of time associated with a worst case of gapexpected between slugs, the zone operating state of such local zone isset to OFF.

Embodiments of the present invention may also be used to prevent back updue to a large grouping of product back to back, which is sometimesreferred to as a slug of product. In traditional models, the slug isbroken up shortly after it enters the accumulation conveyor from itsinfeed, resulting in a backup from the infeed continuing to feed intothe conveyor. In some embodiments of the present disclosure, theaccumulation conveyor 2 is configured to accept the slug from the infeedand the controller 16 is configured to break up the slug furtherdownstream such that the infeed rate is not affected. In suchembodiments, the controller 16 is configured to expect a slug andrestricts a prejam logic or timer from activating. Instead, thecontroller 16 is configured to create one or more gaps in the slugfurther downstream such that the slug is “chopped up.” In oneembodiment, the controller 16 is configured such that one or more zoneswithin the accumulation conveyor 2 apply prejam-detection algorithms tolocate one or more sensors, e.g., photoeyes, that are blocked for aperiod of time corresponding to the longest mini-slug that is expectedequating to a determined maximum period of time. In instances whereinthe controller 16 receives input indicating that a mini-slug longer thanexpected is detected such that one or more sensors are blocked for aperiod of time greater than the determined maximum period of time, thecontroller may be configured to revert the affected local zone toanother accumulation logic, such as singulation. In such embodiments,the local zone and the downstream zone may place a gap between suchzones, chopping the slug into mini-slug bites.

In another embodiment, the controller 16 is configured to re-index aplurality of zones such that one or more zones in a neighborhood areindexed the same to equate to the autoslug size, allowing the product toprogress downstream together. For example, a slug may consist of 100linear feet of product and the controller 16 may be configured torelease 20 linear feet of such product downstream. By re-indexing aplurality of zones, the slug can be backfilled at a faster rate. Insteadof just one zone releasing and backfilling at a time, the controller 16is configured to release multiple zones and backfill multiple zones at atime.

In another embodiment, the controller 16 is configured to apply multiplemethods and zone configurations within a conveyor at the same time. Inexisting accumulation conveyors, the same method or accumulation logicis applied to the entirety of the accumulation conveyor. In someembodiments, it is contemplated that the accumulation logic applied inthe middle of an accumulation conveyor is different than theaccumulation logic applied at the infeed zone of the accumulationconveyor. For example, the accumulation conveyor may require multi-zoneconfigurations in the middle of the conveyor to breakdown a slug, asdisclosed herein, while the zones upstream of such slug are operatingwith the improved, smarter 1-Zone configuration, as described herein,such that the infeed is not slowed down or backed up as a result of theslug breakdown occurring downstream.

In still further embodiments, it is contemplated that two or moreaccumulation conveyors may be configured such that controller 16 appliesor extends the accumulation logic 20 and release logic across themultiple accumulation conveyors to increase throughput. In suchembodiments, the furthest downstream zone in a first conveyor (known asthe terminating zone or discharge zone) looks at the most upstream zoneof the second conveyor, resulting in a back-to-back conveyor system.

In still further embodiments, it is contemplated that even withre-indexing to adjust accumulation aggressiveness, some heavier productlines may require additional zone lengths to slow down to avoid harshimpacts upon stopping product. In such embodiments, the controller 16configures zones upstream of the stopping point as coast zones. In someembodiments, the number of coast zones increases in accordance with oneof the disclosed sliders being adjusted to values translating to lessaggressiveness or lower release rates. In some embodiments, such coastzones are configured as “active” but their speed is configured to zero,allowing the product to coast to the stopping point. As such, the coastzones are ON, allowing products to pass through such zone, but the zoneare not being driven.

In still further embodiments, it is contemplated that even after productaccumulates on the accumulation conveyer 2, gaps may still exist thatneed to be minimized or closed in a gentle, controlled manner. Crowdingis a method that attempts to minimize gaps by pulsing the operatingstate of the local zone between ON and OFF each time product hasaccumulated and stopped, thereby compacting product. In traditionalmethods, the accumulation conveyor is configured such that it waits fordownstream zones to finish crowding before the local zone crowds,resulting in lengthy wait times for upstream zones. Accordingly, in someembodiments, the controller 16 is configured to co-crowd multiple zonessuch that it configures certain zones to crowd simultaneously by pulsingmultiple zones ON and OFF. In one exemplary, non-limiting embodiment,with a co-crowding size of 3, the controller 16 may co-crowd zones 1, 4,and 7 simultaneously by pulsing the operating state of each of zones 1,4, and 7 ON and OFF, and each zone proceed upstream to the next zonerespectively.

If through the crowding process or through user intervention, a localzone's sensor becomes clear, traditional accumulation logic generallyactivates zones upstream to close the gap created, however, such logicwould not crowd the local zone more than once as the local zone itselfwould not have been activated. In still further embodiments, thecontroller 16 is configured to re-crowd one or more zones such that itconfigures certain already crowded zones to crowd again by pulsing thecrowded zones ON and OFF upon the local zone's sensor change (e.g., fromblocked to clear, or clear to blocked). In such embodiments, there-crowding only re-crowds the local zone and a certain number of zoneslocated upstream from the detection of the gap.

In certain embodiments, the controller 16 is configured such that itwill not crowd (or otherwise pulsate ON and OFF the local zone until afirst upstream zone of the local zone is also accumulated, ensuring thatthe local zone is full. In some embodiments, the controller 16 isconfigured to control the terminating or discharge zone at the mostdownstream zone of the accumulation conveyor slightly different. In someembodiments, the controller 16 is configured such that when the localzone is the first or second zone at the discharge end of the conveyor(e.g., Zones 1 and 2), the controller waits for two zones upstream to beaccumulated before activating the crowding function of the local zone,ensuring that the local zone is at rest and ready to be compacted.

In certain embodiments, a crowding tunable accumulation conveyor isdisclosed. The crowding is tuned using an interface similar to theinterfaces disclosed herein with respect to release rate andaggressiveness that instead modifies or adjusts one or more crowdingparameters in accordance with a crowding logic utilizing inputassociated with the interface. For example, in one embodiment, the oneor more crowding parameters comprise variables such as pulse ON time,pulse OFF time, and delay before pulse. In a non-limiting example, acrowding aggressiveness interface with a slider mechanism comprises aslider range, the slider range comprising one or more sections and eachsection is associated with a crowding parameter. As the slider mechanismis adjusted, the crowding logic is configured to modify or adjust thecrowding parameter associated with the corresponding section of theslider range. In some embodiments, each of the one more sections of theslider range modifies or adjusts the corresponding crowding parameter ata different rate. In a further non-limiting example, as the slidermechanism of such a crowding aggressiveness slider is increased, theaggressiveness of the crowding pulses increases.

In some embodiments, the configuration interface, the accumulationaggressiveness interface, the release rate interface, the crowdingaggressiveness interface, and/or other associated interfaces need not bedisplayed or provided to a user. That is, in some embodiments, it iscontemplated that a processor, such as controller 16, associated with anaccumulation conveyor 2, is configured to determine the values of suchrequested variables or data inputs without requiring input from a useror need to display an interface. For example, in some embodiments, thecontroller 16 may be configured to perform a form of self-diagnostictest to determine the data input associated with the accumulationconveyor 2 and associated product and/or values for appropriate producthandling configurations as disclosed herein. For example, based on aknowledge of one or more products being scanned on the accumulationconveyor or receipt of product data from an inventory management system,the system may adjust the appropriate parameters and values forappropriate product handling configurations without the requirement forfurther user input. In some embodiments, certain guidelines may beassociated with different types of products, allowing adjustment of theparameters and values to predetermined configurations based upon atleast the product and conveyor data input.

In still further embodiments, the controller 16, the accumulationconveyor 2, and/or the system may be configured to determine the datainput and/or the appropriate product handling configuration for aconveyor using one or more machine learning techniques or other similartechniques. For example, product attributes such as weight, slickness,and length vary with each package and can further by affected by theseason of the year or shift of the day—all of which affect how productbehaves on a configured accumulation conveyor. Additionally, ratecalculations, sensors, and algorithms capable of detectingaggressiveness levels and/or release rates directly or indirectly, suchas sound, images, rolling averages, and thresholds provide valuableinput for machine learning techniques or other similar techniques.Accordingly, in some embodiments, a product handling configuration maybe determined based upon a machine learning model utilizing such values,variables, parameters and data inputs calculated, received, and/or sentwithin the accumulation conveyor system to identify and/or determinerelationships among the various data inputs. Such machine learningtechniques may implement unsupervised learning techniques, supervisedlearning techniques, reinforcement learning techniques, deep learningtechniques, and/or the like for determining and utilizing relationshipsfor such product handling configuration. Accordingly, such data inputand configuration changes may occur without need for displaying orutilizing a user interface and without user intervention.

The controller 16 of FIG. 1 may be embodied by one or more computingsystems, such as the controller 16 shown in FIG. 2. As illustrated inFIG. 2, in accordance with some example embodiments, the controller 16may include a processor 201, a memory 202, input/output circuitry 203,communications circuitry 204, accumulation circuitry 205, and releasecircuitry 206. The controller 16 may be configured, using one or more ofthe circuitry 201, 202, 203, 204, 205, and 206, to execute theoperations described herein.

Although these components 201-206 are described with respect tofunctional limitations, it should be understood that the particularimplementations necessarily include the use of particular hardware. Itshould also be understood that certain of these components 201-206 mayinclude similar or common hardware. For example, two sets of circuitrymay both leverage use of the same processor, network interface, storagemedium, or the like to perform their associated functions, such thatduplicate hardware is not required for each set of circuitry. The use ofthe term “circuitry” as used herein with respect to components of theapparatus therefore includes particular hardware configured to performthe functions associated with the particular circuitry described herein.

Of course, while the term “circuitry” should be understood broadly toinclude hardware, in some embodiments, circuitry may also includesoftware for configuring the hardware. For example, in some embodiments,“circuitry” may include processing circuitry, storage media, networkinterfaces, input/output devices, and the like. In some embodiments,other elements of the controller 16 may provide or supplement thefunctionality of particular circuitry. For example, the processor 201may provide processing functionality, the memory 202 may provide storagefunctionality, the communications circuitry 204 may provide networkinterface functionality, and the like.

In some embodiments, the processor 201 (and/or co-processor or any otherprocessing circuitry assisting or otherwise associated with theprocessor) may be in communication with the memory 202 via a bus forpassing information among components of the controller 16. The memory202 may be non-transitory and may include, for example, one or morevolatile and/or non-volatile memories. For example, the memory may be anelectronic storage device (e.g., a computer readable storage medium).The memory 202 may be configured to store information, data, content,applications, instructions, or the like, for enabling the controller 16to carry out various functions in accordance with example embodiments ofthe present invention.

The processor 201 may be embodied in a number of different ways and may,for example, include one or more processing devices configured toperform independently. Additionally, or alternatively, the processor 201may include one or more processors configured in tandem via a bus toenable independent execution of instructions, pipelining, and/ormultithreading. The use of the term “processing circuitry” may beunderstood to include a single core processor, a multi-core processor,multiple processors internal to the apparatus, and/or remote or “cloud”processors. Accordingly, although illustrated in FIG. 2 as a singleprocessor, in some embodiments, processor 201 comprises a plurality ofprocessors. The plurality of processors may be embodied on a singleserver or may be distributed across a plurality of such devicescollectively configured to function as controller 16. The plurality ofprocessors may be in operative communication with each other and may becollectively configured to perform one or more functionalities ofcontroller 16 as described herein.

In an example embodiment, the processor 201 may be configured to executeinstructions stored in the memory 202 or otherwise accessible to theprocessor 201. Alternatively, or additionally, the processor 201 may beconfigured to execute hard-coded functionality. As such, whetherconfigured by hardware or software methods, or by a combination ofhardware with software, the processor may represent an entity (e.g.,physically embodied in circuitry) capable of performing operationsaccording to an embodiment of the present invention while configuredaccordingly. Alternatively, as another example, when the processor 201is embodied as an executor of software instructions, the instructionsmay specifically configure the processor 201 to perform the algorithmsand/or operations described herein when the instructions are executed.

In some embodiments, the controller 16 may include input/outputcircuitry 203 that may, in turn, be in communication with processor 201to provide output to the user and, in some embodiments, to receive anindication of user input. The input/output circuitry 203 may comprise auser interface and may include a display and may comprise a web userinterface, a mobile application, a client device, a kiosk, or the like.In some embodiments, the input/output circuitry 203 may also include akeyboard, a mouse, a joystick, a touch screen, touch areas, soft keys, amicrophone, a speaker, or other input/output mechanisms. The processor201 and/or user interface circuitry comprising the processor may beconfigured to control one or more functions of one or more userinterface elements through computer program instructions (e.g., softwareand/or firmware) stored on a memory accessible to the processor 201(e.g., memory 202, and/or the like).

The communications circuitry 204 may be any means such as a device orcircuitry embodied in either hardware or a combination of hardware andsoftware that is configured to receive and/or transmit data from/to anetwork and/or any other device, circuitry, or module in communicationwith the controller 16. In this regard, the communications circuitry 204may include, for example, a network interface for enablingcommunications with a wired or wireless communication network. Forexample, the communications circuitry 204 may include one or morenetwork interface cards, antennae, buses, switches, routers, modems, andsupporting hardware and/or software, or any other device suitable forenabling communications via a network. In some embodiments, it iscontemplated that the communications circuitry 204 is configured to useover the air (OTA) and/or firmware over the air (FOTA) capabilities.Additionally, or alternatively, the communication interface may includethe circuitry for interacting with the antenna(s) to cause transmissionof signals via the antenna(s) or to handle receipt of signals receivedvia the antenna(s).

In some embodiments, the accumulation circuitry 205 includes hardwareand software configured to support accumulation-related functionality,logic, features, and/or services of the controller 16. The accumulationcircuitry 205 may utilize processing circuitry, such as the processor201, to perform these actions. The accumulation circuitry 205 may sendand/or receive data from an accumulation settings repository (notshown). In some implementations, the sent and/or received data mayinclude accumulation parameters and data, such as acceleration values,deceleration values, zone length, neighborhood size, accumulationmodels, prior accumulation installation models and/or the like. In someembodiments, such data is utilized to allow for adjustment ofaggressiveness in a linear fashion by the user while determining thevarious parameters and values to be adjusted in the plurality ofoperational mode settings. It should also be appreciated that, in someembodiments, the accumulation circuitry 205 may include a separateprocessor, specially configured field programmable gate array (FPGA), orapplication specific interface circuit (ASIC).

In some embodiments, the release circuitry 206 includes hardware andsoftware configured to support release-related functionality, logic,features, and/or services of the controller 16. The release circuitry206 may utilize processing circuitry, such as the processor 201, toperform these actions. The release circuitry 206 may send and/or receivedata from one or more repositories, such as the an accumulation settingsrepository or a release rate settings repository (not shown). In someimplementations, the sent and/or received data may include release rateparameters and data, such as release rate values, zone max speed values,zone length(s), and/or the like. In some embodiments, such data isutilized to allow for adjustment of release rates by the user whiledetermining the various parameters and values to be adjusted in theplurality of operational mode settings. It should also be appreciatedthat, in some embodiments, the release circuitry 206 may include aseparate processor, specially configured field programmable gate array(FPGA), or application specific interface circuit (ASIC).

It is also noted that all or some of the information discussed hereincan be based on data that is received, generated and/or maintained byone or more components of the controller 16. In some embodiments, one ormore external systems (such as a remote cloud computing and/or datastorage system) are also leveraged to provide at least some of thefunctionality discussed herein.

Example Operations

Having described the circuitry comprising embodiments of the presentinvention, it should be understood that the controller 16 may control anaccumulation conveyor 2 in a number of ways. FIG. 4A broadly illustratesa flowchart containing a series of operations or blocks performed tocontrol an accumulation conveyor 2 in a product handling environment inaccordance with example embodiments described herein. The operationsillustrated in FIG. 4A may, for example, be performed with theassistance of, and/or under the control of controller 16.

In Block 402, the controller 16 includes means, such as processor 201,input/output circuitry 203, communications circuitry 204, and the like,for receiving conveyor data input, the conveyor data input comprisingconfiguration variables associated with the accumulation conveyor. In anon-limiting example, the conveyor data input is received via userengagement of an aggressiveness configuration interface rendered to acontroller user interface. As described above, in some embodiments, theaggressiveness configuration interface embodies an interactive interfaceconfigured for displaying queries and receiving conveyor data input viauser data input in response to such queries. For example, the queriesdisplayed to the interactive interface include questions posed to theuser that are related to configuration variables associated with theaccumulation conveyor, such as conveyor speed, average zone length, typeof package, average package weight, etc. In other embodiments, theconveyor data input is received via feedback loop or self-test conductedby the accumulation conveyor in order to determine such configurationparameters without requirement of user input or rendering aconfiguration interface.

In Block 404, the controller 16 further includes means, such asprocessor 201, accumulation circuitry 205, and the like, for querying anaccumulation settings repository for accumulation settings based upon atleast the conveyor data input. In some embodiments, the accumulationsettings repository comprises aggressiveness parameters and data, suchas acceleration values, deceleration values, zone length, neighborhoodsize, accumulation models, prior accumulation installation models and/orthe like.

In Block 406, the controller 16 further includes means, such asprocessor 201, accumulation circuitry 205, and the like, for determiningan initial accumulation mode based upon at least the conveyor data inputand the accumulation settings returned by the query, the initialaccumulation mode associated with one or more aggressiveness parameters.In some embodiments, the initial accumulation mode is determined basedupon pre-determined optimal accumulation settings arranged in an arrayin the accumulation settings repository. In further embodiments, theinitial accumulation mode is determined based upon relationshipsidentified among accumulation objects of the accumulating settingsrepository wherein the relationships are programmatically determinedbased upon one or more trained machines learning models.

In Block 408, the controller 16 further includes means, such asprocessor 201, accumulation circuitry 205, and the like, forprogrammatically generating an aggressiveness linear equation based uponat least the accumulation settings returned by the query and at Block410, assigning an aggressiveness value associated with the initialaccumulation mode as a default value of the generated aggressivenesslinear equation. In Block 412, the controller 16 further includes means,such as processor 201, accumulation circuitry 205, and the like, for inresponse to detecting a change in the aggressiveness value, adjusting atleast one of the one or more aggressiveness parameters associated withthe initial accumulation mode in accordance with the aggressivenesslinear equation. For example, in some embodiments, adjusting at leastone of the one or more aggressiveness parameters associated with theinitial accumulation mode in accordance with the aggressiveness linearequation adjusts the level of accumulation aggressiveness associatedwith the accumulation conveyor in comparison to the default value. Forexample, in some embodiments, detecting a change in the aggressivenessvalue corresponds to an indication of decreasing the aggressivenessvalue. In still further embodiments, detecting a change in theaggressiveness value corresponds to an indication of increasing theaggressiveness value.

In Block 414, in an embodiment where user input is required, it isoptionally contemplated that the method may further include rendering anaggressiveness configuration interface to a controller user interface,wherein the conveyor data input is associated with the user engagementof the aggressiveness configuration interface. In Block 416, it isfurther contemplated that the method may further include configuring anaggressiveness interface object based upon at least the aggressivenesslinear equation and the default value and rendering or outputting suchaggressiveness interface object to the controller user interface. Forexample, in an optional embodiment, the aggressiveness interface objectis depicted as a slider like in FIG. 5 and is configured for userengagement. As the user adjusts the slider, the level of aggressivenessis adjusted as compared to the default value of the initial accumulationmode. For example, as the user adjusts the slide to increase theaggressiveness value, the controller 16 includes means, such asprocessor 201, accumulation circuitry 205, and the like for adjustingand stacking one or more operational modes and individual parameters ofthe accumulation conveyor in such as way so as to reflect thecorresponding change in aggressiveness.

FIG. 4B broadly illustrates a flowchart containing a series ofoperations or blocks performed to control an accumulation conveyor 2 ina product handling environment in accordance with example embodimentsdescribed herein. The operations illustrated in FIG. 4B may, forexample, be performed with the assistance of, and/or under the controlof controller 16.

In Block 420, the controller 16 includes means, such as processor 201,input/output circuitry 203, release circuitry 206, and the like, fordetecting an indication to adjust a first release rate associated with afirst zone, wherein the first release rate is separately configurablefrom a level of accumulation aggressiveness of the accumulationconveyor. For example, in some embodiments, an adjustment of a firstrelease rate will have not affect the level of accumulationaggressiveness for the first zone or surrounding zones. In someembodiments, detecting an indication to adjust the first release rateassociated with the first zone is based upon user input received via acontroller user interface

In Block 422, the controller 16 includes means, such as processor 201,release circuitry 206, and the like, for determining a second releaserate associated with the first zone based upon at least a configuredspeed of the first zone and generating a release rate timercorresponding to the second release rate. For example, in someembodiments, the configured speed of the first zone is determined basedupon a percentage of a maximum speed associated with the first zone andthe detected indication to adjust the first release rate. In someembodiments, such maximum speed value may be stored in and/or retrievedfrom a release rate repository.

In Block 424, the controller 16 includes means, such as processor 201,release circuitry 206, and the like, for activating the release ratetimer associated with the first zone. In Block 426, upon expiration ofthe release rate timer associated with the first zone, activating asecond zone, wherein the second zone is upstream of the first zone.

In Block 428, it is optionally contemplated that the method may furtherinclude detecting an indication to adjust a third release rateassociated with a third zone and in Block 430, optionally determining afourth release rate associated with the third zone based upon at least aconfigured speed of the third zone and generating a release rate timercorresponding to the fourth release rate, wherein the fourth releaserate associated with the third zone is different than the second releaserate associated with the first zone. Such an embodiment allows theoptional ability to delineate different areas of zones of theaccumulation conveyor such that one or more areas have differing releaserates is different. For example, a faster release rate may be desiredtoward the discharge end of the conveyor while a slower release rateresulting in more gap may be desired further upstream to allow for nicerupstream handling.

In Block 430, it is optionally contemplated that the method may furtherinclude activating the release rate timer associated with the thirdzone; and in Block 432, activating a fourth zone upon expiration of therelease rate timer associated with the third zone, wherein the fourthzone is upstream of the third zone.

The above descriptions of various embodiments of the subject disclosureand corresponding figures and what is described in the Abstract, aredescribed here for illustrative purposes, and are not intended to beexhaustive or to limit the disclosed embodiments to the precise formsdisclosed. It is to be understood that one of ordinary skill in the artmay recognize that other embodiments having modifications, permutations,combinations, and additions can be implemented for performing the same,similar, alternative, or substitute functions of the disclosed subjectmatter, and are therefore considered within the scope of thisdisclosure. Therefore, the disclosed subject matter should not belimited to any single embodiment described herein, but rather should beconstrued in breadth and scope in accordance with the claims below.

Furthermore, as described above and as will be appreciated based on thisdisclosure, embodiments of the disclosed subject matter may beconfigured or implemented as systems, methods, apparatuses, computingdevices network devices, or articles of manufacture using standardprogramming and/or engineering techniques to produce software, firmware,hardware, or any combination thereof to control a computer to implementthe disclosed subject matter. Accordingly, embodiments may comprisevarious means including entirely of hardware or any combination ofsoftware and hardware.

Embodiments may take the form of a computer program product on at leastone non-transitory computer-readable storage medium havingcomputer-readable program instructions (e.g., computer software)embodied in the storage medium. Similarly, embodiments may take the formof a computer program code stored on at least one non-transitorycomputer-readable storage medium. The term “article of manufacture” asused herein is intended to encompass a computer program accessible fromany computer-readable device, computer-readable carrier, orcomputer-readable media. For example, computer-readable media caninclude, but are not limited to, a magnetic storage device, e.g., harddisk; floppy disk; magnetic strip(s); an optical disk (e.g., compactdisk (CD), a digital video disc (DVD), a Blu-ray Disc′ (BD)); a smartcard; a flash memory device (e.g., card, stick, key drive); and/orvirtual device that emulates a storage device and/or any of the abovecomputer-readable media.and the like. As will be appreciated, any suchcomputer program instructions and/or other type of code may be loadedonto a computer, processor or other programmable apparatus's circuitryto produce a machine, such that the computer, processor, or otherprogrammable circuitry that execute the code on the machine creates themeans for implementing various functions, including those describedherein.

Thus, particular embodiments of the subject matter have been described.While this specification contains many specific implementation details,these should not be construed as limitations on the scope of anyinventions or of what may be claimed, but rather as description offeatures specific to particular embodiments of particular inventions. Inaddition, while a particular feature may have been disclosed withrespect to only one of several implementations, such feature may becombined with one or more other features of the other implementations asmay be desired and advantageous for any given or particular application.Certain features that are described herein in the context of separateembodiments can also be implemented in combination in a singleembodiment. Conversely, various features that are described in thecontext of a single embodiment can also be implemented in multipleembodiments separately or in any suitable sub-combination. Moreover,although features may be described above as acting in certaincombinations and even initially claimed as such, one or more featuresfrom a claimed combination can in some cases be excised from thecombination, and the claimed combination may be directed to asub-combination or variation of a sub-combination.

Similarly, while operations are depicted in the drawings in a particularorder, this should not be understood as requiring that such operationsbe performed in the particular order shown or in sequential order, orthat all illustrated operations be performed, to achieve desirableresults, unless described otherwise. In certain circumstances,multitasking and parallel processing may be advantageous. Moreover, theseparation of various system components in the embodiments describedabove should not be understood as requiring such separation in allembodiments, and it should be understood that the described programcomponents and systems can generally be integrated together in a singlesoftware product or packaged into multiple software products. Anyoperational step shown in broken lines in one or more flow diagramsillustrated herein are optional for purposes of the depicted embodiment.

Many modifications and other embodiments will come to mind to oneskilled in the art to which this disclosure pertains having the benefitof the teachings presented in the foregoing descriptions and theassociated drawings. Therefore, it is to be understood that thedisclosure is not to be limited to the specific embodiments disclosedand that modifications and other embodiments are intended to be includedwithin the scope of the appended claims. Although specific terms areemployed herein, they are used in a generic and descriptive sense onlyand not for purposes of limitation.

The invention claimed is:
 1. An accumulation conveyor system comprising:a conveyor having a plurality of zones; one or more sensors associatedwith each zone of the plurality of zones; one or more control modulesassociated with the plurality of zones; a controller in communicationwith the one or more control modules, the controller comprising at leastone processor and at least one memory, the at least one memory storingexecutable instructions therein, wherein the executable instructions areconfigured to, in execution with the at least one processor, cause thecontroller to: determine whether an item detection variable associatedwith a second zone of the plurality of zones is satisfied, wherein thesecond zone is downstream of a first zone, and wherein the first zone isassigned a local zone number; determine whether at least one of twooperational characteristic variables is satisfied, the two operationalcharacteristic variables comprising a first operational characteristicvariable and a second operational characteristic variable, wherein thesecond operational characteristic variable is satisfied when the localzone number is less than a threshold associated with assignment of localzone numbers; in an instance where both the item detection variable andat least one operational characteristic variable are satisfied, set azone operating state associated with the first zone to inactive; andsend a command signal comprising the zone operating state associatedwith the first zone to the control module associated with the firstzone.
 2. The accumulation conveyor system of claim 1, wherein in aninstance where the item detection variable is not satisfied, theexecutable instructions are further configured to cause the controllerto set the zone operating state associated with the first zone toactive.
 3. The accumulation conveyor system of claim 1, wherein the itemdetection variable associated with the second zone is satisfied when apresence of an object on the conveyor is detected via the one or moresensors associated with the second zone.
 4. The accumulation conveyorsystem of claim 3, wherein at least one of the one or more sensorsassociated with the second zone is a photo eye.
 5. The accumulationconveyor system of claim 4, wherein the item detection variableassociated with the second zone is satisfied when the controllerreceives a blocked signal from the photo eye.
 6. The accumulationconveyor system of claim 1, wherein in an instance where the firstoperational characteristic variable and the second operationalcharacteristic variable are not satisfied, the executable instructionsare further configured to cause the controller to set the zone operatingstate associated with the first zone to active.
 7. The accumulationconveyor system of claim 1, wherein the first operational characteristicvariable is satisfied when a zone operating state associated with thesecond zone is inactive.
 8. The accumulation conveyor system of claim 1,wherein the first zone is associated with a roller countdown timer andthe second operational characteristic variable is satisfied when theroller countdown timer is expired.
 9. The accumulation conveyor systemof claim 8, wherein the roller countdown timer is configured to activateeach instance the zone operating state associated with the first zone isinactive.
 10. The accumulation conveyor system of claim 8, wherein theroller countdown timer is configured to reset each instance the zoneoperating state associated with the first zone is active.
 11. A methodof controlling a release rate of one or more zones of an accumulationconveyor, the method comprising: detecting an indication to adjust afirst release rate associated with a first zone, wherein the firstrelease rate is separately configurable from a level of accumulationaggressiveness of the accumulation conveyor; determining a secondrelease rate associated with the first zone based upon at least aconfigured speed of the first zone and generating a release rate timercorresponding to the second release rate; activating the release ratetimer associated with the first zone; and upon expiration of the releaserate timer associated with the first zone, activating a second zone,wherein the second zone is upstream of the first zone.
 12. The method ofclaim 11, wherein detecting an indication to adjust the first releaserate associated with the first zone is based upon user input receivedvia a controller user interface.
 13. The method of claim 11, furthercomprising: detecting an indication to adjust a third release rateassociated with a third zone; determining a fourth release rateassociated with the third zone based upon at least a configured speed ofthe third zone and generating a release rate timer corresponding to thefourth release rate, wherein the fourth release rate associated with thethird zone is different than the second release rate associated with thefirst zone; activating the release rate timer associated with the thirdzone; and upon expiration of the release rate timer associated with thethird zone, activating a fourth zone, wherein the fourth zone isupstream of the third zone.
 14. The method of claim 11, wherein theconfigured speed of the first zone is determined based upon a percentageof a maximum speed associated with the first zone and the detectedindication to adjust the first release rate.
 15. A method for adjustinga level of accumulation aggressiveness associated with an accumulationconveyor comprising: receiving conveyor data input, the conveyor datainput comprising configuration variables associated with theaccumulation conveyor; querying an accumulation settings repository foraccumulation settings based upon at least the conveyor data input;determining an initial accumulation mode based upon at least theconveyor data input and the accumulation settings returned by the query,the initial accumulation mode associated with one or more aggressivenessparameters; programmatically generating an aggressiveness linearequation based upon at least the accumulation settings returned by thequery; assigning an aggressiveness value associated with the initialaccumulation mode as a default value of the aggressiveness linearequation; and in response to detecting a change in the aggressivenessvalue, adjusting at least one of the one or more aggressivenessparameters associated with the initial accumulation mode in accordancewith the aggressiveness linear equation.
 16. The method of claim 15,wherein adjusting at least one of the one or more aggressivenessparameters associated with the initial accumulation mode in accordancewith the aggressiveness linear equation adjusts the level ofaccumulation aggressiveness associated with the accumulation conveyor incomparison to the default value.
 17. The method of claim 15, whereindetecting a change in the aggressiveness value corresponds to anindication of increasing the aggressiveness value.
 18. The method ofclaim 15, wherein detecting a change in the aggressiveness valuecorresponds to an indication of decreasing the aggressiveness value. 19.The method of claim 15 further comprising: rendering an aggressivenessconfiguration interface to a controller user interface, wherein theconveyor data input is associated with user engagement of theaggressiveness configuration interface; and configuring anaggressiveness interface object based upon at least the aggressivenesslinear equation and the default value and outputting the aggressivenessinterface object to the controller user interface, wherein detecting achange in the aggressiveness value comprises receiving user inputassociated with user engagement of the aggressiveness interface object.